KR102462942B1 - Bypass heat exchanger - Google Patents

Abstract

An object of the present invention is to provide a total heat exchanger for bypass that can be compactly formed by reducing the number of additional parts required to form a bypass flow path and maximizing space efficiency at the same time,
The present invention is a housing shape with an open top, a total heat exchange element is accommodated therein, and an outdoor air intake, an outdoor air discharge, an inside suction and an inside discharge that can communicate with the wall surface are respectively formed, and the outside air a total heat exchange unit having a flow path connecting the suction unit, the total heat exchange element, and the outside air exhaust unit, and a flow path connecting the internal suction unit, the total heat exchange element, and the internal air exhaust unit, respectively; and a cover part covering the upper part of the total heat exchange part. Including, wherein the cover part has a panel shape covering the upper part of the total heat exchange part, and communicates with any two of the outdoor air intake part, the outdoor air exhaust part, the internal intake part and the internal exhaust part which are not connected by the total heat exchange element, respectively. a top cover through which a bypass hole is formed; and a panel-shaped door that opens and closes the top cover. Including, it is characterized in that a flow path through which indoor air or outdoor air can flow without passing through the total heat exchange element is formed.

Description

Bypass heat exchanger {Bypass heat exchanger}

The present invention relates to a total heat exchanger that includes a total heat exchange element and improves energy efficiency by allowing heat exchange between indoor and outdoor air during ventilation. More specifically, the present invention relates to a total heat exchanger for bypass in which a bypass flow path through which indoor air is discharged to the outdoors without passing through a total heat exchange element and an internal circulation flow path through which indoor air is supplied back to the room through the total heat exchange element are formed. it's about

A total heat exchanger is a device for indoor ventilation, in which outdoor air is supplied to the room through the total heat exchange element and the indoor air is discharged to the outdoors through the total heat exchange element, so that heat exchange between the indoor air and the outdoor air is performed in the total heat exchange element. It is a device designed to do this.

More specifically, in the total heat exchanger, a total heat exchange element is disposed in a housing-shaped housing, and an outdoor air intake portion for sucking outdoor air and an outdoor air exhaust portion from which outdoor air is discharged are formed diagonally around the total heat exchange element, The air intake part through which the air is sucked and the indoor air outlet part through which the indoor air is discharged are formed diagonally around the total heat exchange element. The housing is formed with a partition wall dividing the outdoor air intake, outdoor air discharge, inner intake, and inner discharge. In addition, each blowing fan is installed to blow air forcibly on the side of the outside air discharge unit and the inside discharge unit where the air is discharged, and a filter is installed at the outside air suction unit and the inside suction unit from which air is sucked. Furthermore, it has a structure in which an electric damper for opening and closing the flow path can be installed on the side of the outside air discharge unit and/or the outside air discharge unit.

Bypass means to form an additional flow path in addition to the flow path of the above-described total heat exchanger to blow air so as not to pass through the total heat exchange element, and internal circulation means a configuration for sucking indoor air and supplying it back to the room. Furthermore, it may be referred to as a total heat exchanger for bypass in combination with all of the above-described bypass and internal circulation.

The conventional total heat exchanger for bypass constitutes the bypass flow path by adding a separate pipe or forming a hole for the bypass in the bulkhead in the housing. However, the method of using a separate pipe has disadvantages in that the cost increases due to the addition of parts and the space efficiency is also reduced. Even in this case, there is a problem in that the space efficiency is low and the volume of the product is increased.

The present invention is to solve the problems of the prior art as described above, specifically, by reducing the number of additional parts required to form the bypass flow path and the internal circulation flow path, and at the same time maximizing the space efficiency to be compactly formed. An object of the present invention is to provide a total heat exchanger for the pass.

An embodiment of the present invention provides a total heat exchanger for bypass as follows in order to solve the above problems.

The present invention is a housing shape with an open top, a total heat exchange element is accommodated therein, and an outdoor air intake, an outdoor air discharge, an inside suction and an inside discharge that can communicate with the wall surface are respectively formed, and the outside air a total heat exchange unit having a flow path connecting the suction unit, the total heat exchange element, and the outside air exhaust unit, and a flow path connecting the internal suction unit, the total heat exchange element, and the internal air exhaust unit, respectively; and a cover part covering the upper part of the total heat exchange part. including, wherein the cover part has a panel shape covering the upper part of the total heat exchange part, and communicates with any two of the external air intake part, the outdoor air exhaust part, the internal intake part and the internal exhaust part which are not connected by the total heat exchange element a top cover through which each bypass hole is formed; and a panel-shaped door that opens and closes the top cover. and a bypass passage connecting the bypass hole is formed between the top cover and the door.

In addition, the bypass hole is formed to communicate with the inside air discharge unit and the outside air discharge unit, and indoor air is discharged to the outside through the outside air discharge unit, the bypass flow path and the inside air discharge unit, or indoor air is discharged to the outside through the inside air intake unit, heat transfer It is characterized in that it is formed so as to be supplied back into the room through the exchange element, the bypass flow path and the outdoor air exhaust unit.

In addition, the cover part may include: a damper for opening and closing the bypass hole; It is characterized in that it further comprises.

In addition, the total heat exchange unit, a first blowing fan installed on the side of the outdoor air outlet; a second blowing fan installed on the side of the bet discharge unit; and an electric damper installed on the side of the outdoor air intake. Further comprising, when the damper is opened and the second blowing fan is driven, the first blowing fan is not driven and the electric damper is closed, when the damper is opened and the first blowing fan is driven , The second blowing fan is not driven and the electric damper is closed.

In addition, the door, characterized in that the first bypass passage connecting the bypass hole communicating with the outside air outlet and the bypass hole communicating with the outside air outlet is formed in the door.

In addition, in the top cover, a bypass hole communicating with the indoor air outlet and a second bypass passage connecting the bypass hole to the outdoor air outlet and having a shape corresponding to the first bypass passage are formed. do.

In addition, the first bypass flow path and the second bypass flow path may be formed such that a flow path width in a central portion thereof is smaller than a portion in which the bypass hole is formed.

In addition, the top cover and the door are hinge-coupled, and a hinge body protruding from one edge and extending in a direction different from that of the hinge body are formed on the door, and a hinge coupling protrusion protruding in a direction different from the extension direction of the hinge body is formed in the top cover, A hinge coupling groove is recessed so that the hinge coupling protrusion is inserted and rotatable, and the hinge coupling groove is formed in a rectangular groove shape elongated in a direction perpendicular to the rotation of the hinge coupling protrusion, wherein the hinge coupling protrusion is the hinge It is characterized in that it is slidably coupled within the coupling groove.

In addition, the hinge-engaging groove has a rectangular groove shape extending from a first position where the hinge-engaging protrusion is located in the closed state to a second position where the hinge-engaging protrusion is located in the open state of the door, The second position is characterized in that it is located in a diagonal direction from the first position toward the upper center.

In addition, the total heat exchange unit further includes a filter installed to be in contact with the inside suction unit or the outside air suction unit so as to be in contact with the total heat exchange element, and the top cover has a replacement hole into which the total heat exchange element and the filter can be inserted. It is formed through, and the top cover further includes a fall prevention bracket disposed in parallel with the top cover on one side of the replacement hole and rotatably installed, and the fall prevention bracket is formed in a shape eccentric from the installed rotation shaft. and covers a portion of the replacement hole in a position rotated toward the total heat exchange element, and is formed to completely open the replacement hole in a position rotated in the opposite direction of the total heat exchange element.

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

According to the present invention, the same flow path can be used as the bypass flow path and the internal circulation flow path, so that one flow path can be used according to the situation. Furthermore, since the bypass flow path and the internal circulation flow path can be formed without providing a separate pipe or space, the number of parts required for adding the flow path can reduce costs, and the product can be miniaturized due to good space efficiency.

In addition, by forming a neck part in the bypass flow path, spatial interference with the total heat exchange element can be reduced, so that the product can be manufactured more compactly.

Furthermore, when the door is opened, the hinge coupling part from the top cover slides open by gravity, thereby reducing interference in the hinge part and increasing the opening angle.

In addition, by applying the fall prevention bracket, it is possible to prevent the total heat exchange element or filter from falling from the ceiling when the door is opened. Therefore, the replacement operation of the total heat exchange element and the filter can be performed safely.

1 is a schematic diagram showing an installation state of the total heat exchanger for bypass of the present invention;
2 is a perspective view in which the door of the total heat exchanger for bypass of the present invention is disposed upward;
3 is a plan view showing the internal configuration of a total heat exchange unit;
4 is a plan view when the top cover is mounted on the total heat exchange unit, and is a view showing that a bypass flow path is formed;
5 is a plan view when the top cover is mounted on the total heat exchange unit, and is a view showing that an internal circulation flow path is formed;
6 is a bottom view of the top cover;
7 is an exploded view of part VI in FIG. 2 , and is a partially enlarged view showing the details of the hinge coupling structure of the door and the top cover;
Fig. 8 is a perspective view showing when the door is closed and opened in Fig. 7, respectively;
9 is a plan view for explaining the operation of the fall prevention bracket.

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

1 is a schematic view showing an installation state of the total heat exchanger for bypass of the present invention, FIG. 2 is a perspective view with the door of the total heat exchanger for bypass of the present invention disposed upward, and FIG. 3 is a plan view showing the internal configuration of the total heat exchanger , FIG. 4 is a plan view when the top cover is mounted on the total heat exchange unit, showing that a bypass flow path is formed, and FIG. 6 is a bottom view of the top cover.

As shown in these drawings, in one embodiment of the present invention, a total heat exchange unit 200 in which a total heat exchange element 230 is accommodated and a flow path for heat exchange of indoor and outdoor air is formed, and a total heat exchange unit 200. It is assembled on the upper surface and includes a cover part 100 that is formed to be able to open and close.

The present invention can be installed in the space between the ceiling wall (1) and the ceiling surface (1') as shown in Figure 1, the total heat exchange unit 200 is installed inside the ceiling surface (1'), the cover The cover part 100 is installed to be positioned at the lower side so that the door 110 of the part 100 can be opened in the interior direction. However, in this specification, for convenience of explanation, it is described that the door 110 is positioned at the upper side with respect to that shown in FIG. 2 .

In the total heat exchange unit 200, as described above, the total heat exchange element 230 is disposed in the housing 210 of the enclosure shape, the outdoor air intake part 241 through which outdoor air is sucked, and the outdoor air discharge unit through which the outdoor air is discharged. 242 is formed diagonally around the total heat exchange element 230, and the indoor air intake part 243 through which the indoor air is sucked and the indoor air outlet part 244 through which the indoor air is discharged are diagonally around the total heat exchange element. is formed The housing 210 has a partition wall 211 that divides the outdoor air suction unit 241 , the outside air discharge unit 242 , the inside suction unit 243 , and the inside discharge unit 244 is formed. In addition, each blowing fan 220 is installed to forcibly blow air on the side of the outdoor air discharge unit 242 and the inside air discharge unit 244 from which the air is discharged, and the outside air suction unit 241 and the inside suction through which air is sucked. A filter 260 is installed on the part 243 side. Furthermore, the outside air discharge unit 244 and/or the outside air discharge unit 242 side has a structure in which an electric damper 250 for opening and closing the flow path can be installed.

The cover part 100 covers the upper part of the total heat exchange part 200 housing 210, and forms a flow path in the housing 210 by sealing the upper surface of the housing 210, and a total heat exchange element 230 or a filter ( It includes a top cover 130 formed to be replaceable 260 , and a door 110 hinged to open and close the upper surface of the top cover 130 .

The top cover 130 includes a top cover body 131 that covers the upper portion of the total heat exchange unit 200 and forms a flow path together with the housing 210 and the partition wall 211 of the total heat exchange unit 200 . In the top cover body 131, the bypass hole 134 communicating with the outdoor air outlet 242 and the indoor air outlet is formed through the corresponding positions, respectively, and a damper that opens and closes the bypass hole 134 by rotation. 150 may be provided electrically.

In addition, the top cover body 131 may have a second bypass passage 132 connecting the two bypass holes 134 communicating with the outdoor air outlet 242 and the indoor air outlet, respectively. The second bypass flow path 132 may be formed in a groove shape concave downward from the upper surface of the top cover body 131 as shown in the drawings, or may have ribs formed upward along the flow path shape unlike in the drawings. The second bypass flow path 132 forms one flow path together with the above-described first bypass flow path 111 .

The second bypass passage 132 may form a neck portion 132b that is narrower in width than the portion 132a in which the damper 150 is installed in the center. Forming the neck 132b is to make the product more compact, and since the total heat exchange element 230 is usually formed in a rectangular shape, the vertex portion of the total heat exchange element 230 is located near the neck, thereby reducing the size of the product. can do.

In addition, in the top cover body 131, a replacement hole 133 is formed so that the total heat exchange element 230 and the filter 260 can be withdrawn upwardly at positions corresponding to the total heat exchange element 230 and the filter 260. can be The replacement hole 133 is for allowing the user to replace the total heat exchange element 230 and the filter 260 according to a predetermined period.

Furthermore, a bracket fastening hole 135 is formed through the outside of one edge of the replacement hole 133, which is for installing a fall prevention bracket 160 to be described later, and enables the fall prevention bracket 160 to be rotatable. As long as it can be installed, any structure other than the hole is acceptable.

The door 110 may include a door body 112 covering an upper surface of the top cover 130 . A first bypass passage 111 may be formed in the door body 112 . The first bypass passage 111 is formed in a structure that can be engaged with the second bypass passage 132 formed in the top cover body 131 . For example, the second bypass flow path 132 is formed in a groove structure in which a recess is formed on the top surface of the top cover body 131 , and the first bypass flow path 111 is formed on the lower surface of the door 110 , It may be formed to protrude in the form of a rib that can be inserted into the second bypass passage 132 . Also, like the second bypass passage 132 , the first bypass passage 111 may form a neck portion 111b that is narrower than the portion 111a in which the damper 150 is installed in the central portion. Therefore, in the present invention, the bypass flow path can be configured compactly by additionally forming the flow path at the portion where the height difference between the height of the housing 210 of the total heat exchange unit 200 and the height of the blower fan 220 occurs.

The flow path additionally formed by the above-described configuration may be used as a bypass flow path and an internal circulation flow path. 4 and 5, the air flow directions along the bypass flow path and the internal circulation flow path are respectively indicated by arrows.

First, when using as a bypass flow path as shown in FIG. 4 , the blower fan 220 on the side of the exhaust outlet 244 is driven, and the damper 150 installed in the top cover 130 is opened, and between the door 110 and the A bypass flow path may be formed in the . Accordingly, the indoor air can be directly discharged from the indoor to the outdoors without passing through the total heat exchange element 230 through the outdoor air discharge unit 242 , the bypass flow path, and the inside discharge unit 244 .

In addition, when used as an internal circulation flow path, the blowing fan 220 on the outside air outlet 242 side is driven, the damper 150 installed on the top cover 130 is opened, and the internal circulation flow path between the door 110 and the door 110 is opened. can be formed. In this case, it is preferable to maintain the closed state of the electric damper 250 on the side of the outdoor air intake 241 of the total heat exchange unit 200 . Therefore, the indoor air may be supplied back into the room through the internal intake part 243 , the total heat exchange element 230 , the internal circulation flow path, and the outdoor air exhaust part 241 . Furthermore, it is preferable that the filter 260 installed on the side of the inner suction part 243 further includes a HEPA filter in addition to the pre-filter, which is to exhibit an air purifying function when used as an internal circulation passage.

On the other hand, it is preferable that the internal circulation function is made selectively with ventilation. Therefore, the blower fan 220 and the damper 150, the damper 150 closes the bypass hole 134 when the blowing fan 220 installed on the side of the bet discharge unit 244 is operated, and the bet discharge unit 244 ) when the blowing fan 220 installed on the side does not operate, the damper 150 may be operated to open the bypass hole 134 . First, since the internal circulation flow path is closed by the damper 150 when the blowing fan 220 installed on the side of the bet discharge unit 244 is operated, the air in the room is supplied to the inside suction unit 243, the total heat exchange element ( 230), it may be discharged to the outside through the bet discharge unit 244 side blowing fan 220 and the bet discharge unit 244. In addition, when the ventilation fan 220 on the inside exhaust part 244 side does not operate, since the internal circulation flow path is opened, the indoor air is supplied to the inside intake part 243, total heat exchange element 230, bypass flow path, outdoor air exhaust part. It may be supplied back into the room through the 242 side blowing fan 220 and the outdoor air discharge unit 242 .

In addition, the door body 112 may further include a cushion 113 corresponding to the replacement hole 133 described above. The cushion 113 is formed of an elastic material to have elasticity in the vertical direction, and as the cushion 113 is provided, when the door 110 is opened and closed, the collision sound and impact with the total heat exchanger 10 and the filter 260 are reduced. There is an effect that can be done.

FIG. 7 is an exploded view of part VI in FIG. 2 , and is a partially enlarged view showing the details of the hinge coupling structure of the door and the top cover, FIG. 8 (a) is when the door is closed in FIG. (b) is a perspective view which shows when a door is opened, respectively. The hinge structure of the door 110 and the top cover 130 in the present invention will be described with reference to these drawings.

The door 110 and the top cover 130 body may include a door coupling part 120 and a top cover coupling part 140, respectively, and the door 110 may be rotatably coupled with respect to one corner.

The door coupling part 120 includes a hinge body 121 that protrudes from one corner and is formed to extend, and a hinge coupling protrusion 121 that protrudes from the hinge body 121 and protrudes in a different direction from the hinge body 121. Thus, the door 110 can be hinged to the top cover 130 . In addition, fastening hooks 123 for maintaining the closed state of the door 110 may be formed in corners other than the corners where the hinge body 121 is formed.

In addition, the top cover coupling portion 140 has a hinge coupling groove 141 to which the hinge coupling protrusion 121 is coupled is formed in a concave shape, the hinge coupling recess 141 is an insertion part (in which the hinge coupling protrusion 121) can be inserted. 141a), a first position 141b at which the hinge coupling protrusion 121 is positioned in a closed position of the door 110, and a position spaced apart from the first position 141b and hinged at an open position of the door 110 It is formed to include a second position 141c that is the position of the protrusion 121 . That is, when the door 110 is opened and closed, the hinge coupling protrusion 121 is formed to be slidably movable within the hinge coupling groove 141 .

In addition, a guide protrusion 142 may be formed to prevent the hinge coupling protrusion 121 from being unintentionally separated through the insertion part 141a. The guide protrusion 142 is formed between the insertion part 141a and the first position 141b, and the hinge coupling protrusion 121 is guided from the first position 141b to the second position 141c. can

The second position 141c is preferably formed above the first position 141b to be moved by the load of the door 110 when the door 110 is opened. Furthermore, the second position 141c is preferably located on the upper surface center side of the total heat exchanger 10 rather than the first position 141b in order to increase the opening angle of the door 110 . That is, the second position 141c may be located in a diagonal direction from the first position 141b.

When the door 110 is opened while the total heat exchanger 10 of the present invention is installed on the ceiling by the sliding structure of the hinge of the door 110, the load of the door 110 and the shape of the hinge coupling groove 141 cause the door ( Since the hinged portion of the 110 is moved inward from the edge, it is possible to reduce the interference between the door 110 and the top cover 130 and increase the opening angle of the door 110 .

In addition, the top cover coupling part 140 is formed in a complementary shape to the fastening hook 123 of the door 110 and includes the hook coupling part 143 engaged with each other to maintain the closed state of the door 110 .

9 is a plan view for explaining the operation of the fall prevention bracket. With reference to FIG. 9, the bracket 160 for preventing a fall in the present invention will be described.

The total heat exchange element 230 and the filter 260 are coupled in a structure not to be separated while being inserted into the total heat exchange unit 200, but may fall due to a gap that occurs due to poor fastening and aging. The fall prevention bracket 160 blocks one side of the replacement hole 133, which is the insertion hole of the total heat exchange element 230 and the filter 260, so that the total heat exchange element 230 and the filter 260 are installed in the total heat exchange unit 200. It is configured to prevent falling away from the housing 210 .

The fall prevention bracket 160 is coupled to the bracket fastening hole 135 formed in the top cover body 131, and is rotatably installed based on the bracket fastening hole 135, and is eccentric to one side based on the rotation axis. It may include a stopper 162 that is installed within the rotation radius of the bracket body 161 formed in the shape to limit the rotation angle of the bracket body 161. The bracket body 161 may be formed in the shape of a sector as shown in the drawing as an example.

The bracket body 161 is rotated in one direction so as to be located in the opposite direction of the total heat exchange element 230 and is for replacement so that the total heat exchange element 230 and the filter 260 can be drawn out as shown in FIG. It does not interfere with the hole 133 and blocks the total heat exchange element 230 and the filter 260 as shown in FIG. Therefore, it is possible to prevent the total heat exchange element 230 or the filter 260 from falling while the door 110 is open due to the fall prevention bracket 160 .

In the present specification, each configuration has been described in detail, but embodiments that can be derived by arbitrarily combining some configurations also fall within the scope of the present invention.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains can make various modifications and variations without departing from the essential characteristics of the present invention. The scope of protection should be construed by the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

1 ceiling wall 1' ceiling surface
10 Total heat exchanger 100 Cover part
110 door 111 first bypass flow path
112 Door body 113 Cushion
120 Door coupling part 121 Hinge body
121 Hinge coupling protrusion 123 Fastening hook
130 top cover 131 top cover body
132 2nd bypass flow path 133 Replacement hole
134 bypass hole 135 bracket fastening hole
140 Top cover coupling part 141 Hinge coupling groove
142 Guide projection 143 Hook coupling part
150 Damper 160 Bracket for fall prevention
161 Bracket body 162 Stopper
200 Total Heat Exchanger 210 Housing
211 bulkhead 220 blower fan
230 Total heat exchange element 241 Outside air intake
242 Outside air outlet 243 Intake unit
244 Bet discharge unit 250 Electric damper
260 filter

Claims (10)

delete delete delete It has a box shape with an open top, a total heat exchange element is accommodated therein, and an outdoor air intake, an outdoor air discharge, an inside suction and an inside exhaust through which air can communicate are formed on the wall, respectively, and the outside air intake and heat transfer a total heat exchange unit having a flow path connecting the exchange element and the outdoor air exhaust unit, and a flow path connecting the internal suction unit, the total heat exchange element, and the internal air exhaust unit, respectively; and
a cover part covering the upper part of the total heat exchange part;
includes,
The cover part,
It has a panel shape covering the upper part of the total heat exchange part, and a bypass hole communicating with any two of the outdoor air intake part, the outdoor air exhaust part, the internal intake part and the internal exhaust part not connected by the total heat exchange element is formed through each top cover;
a panel-shaped door that opens and closes the top cover; and
a damper for opening and closing the bypass hole;
includes,
A bypass passage connecting the bypass hole is formed between the top cover and the door,
The bypass hole is formed to communicate with the inside air discharge unit and the outside air discharge unit,
It is formed so that indoor air is discharged to the outdoors through the outdoor air discharge unit, the bypass flow path and the inside exhaust unit, or indoor air is supplied back into the room through the inside air suction unit, the total heat exchange element, the bypass flow path and the outside air discharge unit,
The total heat exchange unit,
a first blowing fan installed on the side of the outdoor air outlet;
a second blowing fan installed on the side of the bet discharge unit; and
an electric damper installed on the side of the outdoor air intake;
further comprising,
When the damper is opened and the second blowing fan is driven, the first blowing fan is not driven and the electric damper is closed,
When the damper is opened and the first blowing fan is driven, the second blowing fan is not driven and the electric damper is closed.
It has a box shape with an open top, a total heat exchange element is accommodated therein, and an outdoor air intake, an outdoor air discharge, an inside suction and an inside exhaust through which air can communicate are formed on the wall, respectively, and the outside air intake and heat transfer a total heat exchange unit having a flow path connecting the exchange element and the outdoor air exhaust unit, and a flow path connecting the internal suction unit, the total heat exchange element, and the internal air exhaust unit, respectively; and
a cover part covering the upper part of the total heat exchange part;
includes,
The cover part,
It has a panel shape covering the upper part of the total heat exchange part, and a bypass hole communicating with any two of the outdoor air intake part, the outdoor air exhaust part, the internal intake part and the internal exhaust part not connected by the total heat exchange element is formed through each top cover; and
a panel-shaped door that opens and closes the top cover;
includes,
A bypass passage connecting the bypass hole is formed between the top cover and the door,
The bypass hole is formed to communicate with the inside air discharge unit and the outside air discharge unit,
It is formed so that indoor air is discharged to the outdoors through the outdoor air discharge unit, the bypass flow path and the inside exhaust unit, or indoor air is supplied back into the room through the inside air suction unit, the total heat exchange element, the bypass flow path and the outside air discharge unit,
A total heat exchanger for bypass, characterized in that the door has a first bypass passage connecting a bypass hole communicating with the indoor air outlet and a bypass hole communicating with the outdoor air outlet.
6. The method of claim 5,
In the top cover, a bypass hole communicating with the indoor air outlet and a second bypass passage connecting the bypass hole to the outside air outlet and having a shape corresponding to the first bypass passage are formed. Total heat exchanger for bypass.
7. The method of claim 6,
The total heat exchanger for bypass, characterized in that the first bypass flow path and the second bypass flow path are formed to have a flow path width smaller in a central portion than in a portion in which the bypass hole is formed.
It has a box shape with an open top, a total heat exchange element is accommodated therein, and an outdoor air intake, an outdoor air discharge, an inside suction and an inside exhaust through which air can communicate are formed on the wall, respectively, and the outside air intake and heat transfer a total heat exchange unit having a flow path connecting the exchange element and the outdoor air exhaust unit, and a flow path connecting the internal suction unit, the total heat exchange element, and the internal air exhaust unit, respectively; and
a cover part covering the upper part of the total heat exchange part;
includes,
The cover part,
It has a panel shape covering the upper part of the total heat exchange part, and a bypass hole communicating with any two of the outdoor air intake part, the outdoor air exhaust part, the internal intake part and the internal exhaust part not connected by the total heat exchange element is formed through each top cover; and
a panel-shaped door that opens and closes the top cover;
includes,
A bypass passage connecting the bypass hole is formed between the top cover and the door,
The top cover and the door are hinged,
A hinge body protruding from one corner and extending is formed on the door, and a hinge coupling protrusion protruding in a direction different from the extension direction of the hinge body,
A hinge coupling groove is formed in the top cover to be rotatably inserted by the hinge coupling protrusion,
The hinge coupling groove is formed in a rectangular groove shape elongated in a direction perpendicular to the rotation of the hinge coupling protrusion, and the hinge coupling protrusion is slidably coupled within the hinge coupling groove. .
9. The method of claim 8,
The hinge coupling groove has a rectangular groove shape extending from a first position at which the hinge coupling protrusion is located in the closed state of the door to a second position at which the hinge coupling protrusion is located in an open state,
The second position is a total heat exchanger for bypass, characterized in that it is located in a diagonal direction from the first position toward the upper center.
It has a box shape with an open top, a total heat exchange element is accommodated therein, and an outdoor air intake, an outdoor air discharge, an inside suction and an inside exhaust through which air can communicate are formed on the wall, respectively, and the outside air intake and heat transfer a total heat exchange unit having a flow path connecting the exchange element and the outdoor air exhaust unit, and a flow path connecting the internal suction unit, the total heat exchange element, and the internal air exhaust unit, respectively; and
a cover part covering the upper part of the total heat exchange part;
includes,
The cover part,
It has a panel shape covering the upper part of the total heat exchange part, and a bypass hole communicating with any two of the outdoor air intake part, the outdoor air exhaust part, the internal intake part and the internal exhaust part not connected by the total heat exchange element is formed through each top cover; and
a panel-shaped door that opens and closes the top cover;
includes,
A bypass passage connecting the bypass hole is formed between the top cover and the door,
The total heat exchange unit further comprises a filter installed so as to be in contact with the internal air suction unit or the outside air suction unit so as to be in contact with the total heat exchange element,
A replacement hole through which the total heat exchange element and the filter can be inserted is formed in the top cover,
The top cover further includes a bracket for preventing a fall which is arranged in parallel with the top cover on one side of the replacement hole and is rotatably installed,
The fall prevention bracket is formed in a shape eccentric from the installed rotation shaft, covers a part of the replacement hole at a position rotated toward the total heat exchange element, and the replacement hole at a position rotated in the opposite direction of the total heat exchange element A total heat exchanger for bypass, characterized in that it is formed to open all of the.

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