KR20170034878A - Ventilating apparatus having by-pass function - Google Patents

Abstract

The present invention relates to a bypass member and a ventilating device including the same. The present invention includes: a casing including an inflow passage guiding outward air to the inside, and a discharge passage guiding indoor air to the outside; a total heat exchanger installed in the casing to be connected with the inflow passage and the discharge passage, and exchanging heat between the outdoor air, flowing through the inflow passage, and the indoor air discharged through the discharge passage; a bypass member installed outside the casing, and including a discharge bypass passage inducing the indoor air, discharged through the discharge passage, to go through the discharge passage without passing the total heat exchanger, and an inflow bypass passage inducing the outdoor air, flowing through the inflow passage, to go through the inflow passage without passing the total heat exchanger; a first damper opening or closing the discharge bypass passage; and a second damper opening or closing the inflow bypass passage. According to the present invention, the device is capable of minimizing a loss of heat indoors in summer or winter, in which there is a large temperature difference between indoor and outdoor areas, and reducing the flow resistance of air in spring or fall.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a ventilation apparatus having a bypass function,

The present invention relates to a ventilator having a bypass function.

Generally, if a person is in a room for a long period of time in a room where the interior of the building is not well ventilated from outside, it is necessary to ventilate the room because the room air can not be kept comfortable due to pollution and CO2 increase. Opening a window and ventilation will cause not only pollution but also internal heat loss. In order to solve such a problem, a ventilation system equipped with an enthalpy heat exchanger is installed in a building.

The ventilation system is installed on the wall of the building and includes a ventilation device equipped with an enthalpy heat exchanger, an air inflow pipe line connected to the ventilation device installed inside the building so as to be connected to the inside of the building, And an air discharge line connected to the ventilator.

1 is a plan view showing an example of a ventilator. 1, the ventilating apparatus includes a casing 10 provided on a wall of a building, which is provided with an inflow passage 11 and a discharge passage 12 and is positioned over the inside and outside of the building, A total enthalpy heat exchanger 20 provided in the casing 10 for exchanging heat with air passing through the inflow passage 11 and the discharge passage 12 and an exhaust fan motor 20 disposed in the discharge passage 12 of the casing 10, (30), and an intake fan motor (40) provided in the intake flow path (11) of the casing (10) and positioned on the indoor side. A discharge duct PO and an inlet duct PI are connected to the outer surface of one side plate of the casing 10 so that the discharge duct PO communicates with the discharge passage 12 and the inlet duct PI communicates with the inlet passage 11, . And a damper D for opening and closing the flow passage is provided on the side of the discharge duct and the side of the inflow duct. The air inlet pipe line LI and the air outlet pipe line LO are connected to the outer surface of the other side plate of the casing 10 and the air inlet pipe line LI is communicated with the inlet flow path 11, The line LO communicates with the discharge flow passage 12. The total enthalpy heat exchanger (20) includes a plurality of stacked unit filters.

The operation of the ventilation system is as follows.

When the exhaust fan motor 30 and the intake fan motor 40 of the ventilator operate, the outdoor air is supplied to the room through the inflow channel 11 and the air inflow pipe line LI of the casing 10 , The indoor air is discharged to the outside through the air discharge piping line (LO) and the discharge flow path (12) of the casing (10). The outdoor air flowing into the inflow channel 11 of the casing 10 and the indoor air discharged into the discharge flow passage 12 are exchanged with each other while passing through the total enthalpy heat exchanger 20 and the heat exchanged outdoor air is supplied to the room do.

The damper D provided in the inlet duct PI and the outlet duct PO is opened when the ventilation fan motor 30 and the intake fan motor 40 of the ventilating apparatus are respectively operated, The damper D provided in each of the inlet duct PI and the discharge duct PO is closed when the intake fan motor 30 and the intake fan motor 40 are not operated.

However, the structure described above effectively exchanges heat between outdoor air flowing into the room through the total enthalpy heat exchanger and indoor air discharged to the outside during winter or summer when the temperature difference between indoor and outdoor is great. However, There is a disadvantage in that the total heat exchanger does not play a large role in spring or fall, which is not great, and only the flow resistance of the air is generated.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a ventilating apparatus having a bypass function for minimizing indoor heat loss during winter or summer when the temperature difference between indoor and outdoor is large and reducing the flow resistance of air in spring or autumn.

In order to accomplish the object of the present invention, there is provided an air conditioner comprising: a casing having an inflow passage for guiding outdoor air into the room; and a discharge passage for guiding the indoor air to be discharged outdoors; A total enthalpy heat exchanger mounted in the casing so that the inflow passage and the discharge passage are connected to each other, the indoor heat exchanger exchanging the outdoor air introduced into the inflow passage and the indoor air discharged into the discharge passage; An exhaust bypass flow passage provided outside the casing for guiding indoor air discharged through the discharge flow passage to pass through the discharge flow passage without passing through the total enthalpy heat exchanger, A bypass member including an inlet bypass flow path for guiding the air to pass through the inflow passage without passing through an exchange; A first damper for opening / closing the discharge bypass passage; And a second damper for opening and closing the inflow bypass flow path.

The bypass member includes first and second discharge cap portions that are respectively located on both sides of the total enthalpy heat exchanger and are coupled to the outer surface of the casing so as to communicate with the discharge flow passage, A first and a second inflow cap portions respectively disposed on both sides of the total enthalpy heat exchanger and connected to the outer side surface of the casing so as to communicate with the inflow passage; And an inlet bypass duct for communicating the first and second inlet cap portions, wherein the first and second outlet cap portions and the discharge bypass duct portion form a discharge bypass flow passage, and the first and second inlet cap portions and the inlet bypass And the duct portion may form the inlet bypass flow path.

Wherein the discharge bypass duct portion and the inlet bypass duct portion intersect with each other, wherein an intersecting groove is formed at an upper side of the discharge bypass duct portion and an intersecting groove is provided at a lower side of the inflow bypass duct portion, It is preferable that the intersecting groove and the intersecting groove of the inflow bypass duct portion are engaged with each other.

Preferably, the first and second discharge cap portions and the first and second inlet cap portions are each formed in a cylindrical shape with a top surface blocked, and each of the discharge bypass duct portion and the inlet bypass duct portion is a rectangular tube having a square cross section.

The bypass member includes a body portion having an inner space, a partition wall portion serving as a heat exchanger for partitioning the inner space of the body portion into an upper passage and a lower passage, a first lower duct communicating one side of the lower passage with one side of the discharge passage, A first upper duct portion communicating one side of the upper flow path and one side of the inflow passage; a second upper duct portion communicating with the other side of the upper flow path and the inflow And a second upper duct portion communicating the other side of the flow path, wherein the lower flow path, the first and second lower duct portions constitute the discharge bypass flow path, and the upper flow path and the first and second upper duct portions are connected to the flow- .

(Terminal area) of the lower flow path of the body part constituting the discharge bypass flow path is larger than each volume (terminal area) of the first and second lower duct parts and the volume of the upper flow path of the body part constituting the inflow bypass flow path Sectional area) is larger than each volume (terminal area) of the first and second upper duct portions.

It is preferable that the upper surface and the lower surface of the body portion are octagonal plates, and the side surfaces thereof are formed in the shape of an octagonal cylinder in which eight rectangular plates are continuously connected.

The present invention effectively exchanges heat between outdoor air flowing into a room through indoor heat exchangers and indoor air discharged into an outdoor space during a winter season or a summer season where indoor and outdoor temperature differences are large, thereby minimizing heat loss in a room, Air or hot air will not enter the room, thus maintaining a comfortable indoor condition. In the spring or autumn season when the temperature difference between the indoor and the outdoor is not large, the outdoor air flowing into the room and the indoor air discharged to the outside flow through the inlet bypass flow and the discharge bypass flow without passing through the total enthalpy heat exchanger, So that the driving power of the motor is reduced and the noise is minimized.

The present invention also relates to an air conditioner for a vehicle, comprising: an outdoor air passage for passing outdoor air flowing into an indoor space through an inlet bypass passage; Even if the temperature difference between the indoor and the outdoor is not large, the heat loss of the room is minimized because the heat of the indoor air is transmitted to the outdoor air through the partition wall portion. Further, the lower flow path of the body portion constituting the discharge bypass flow path has a volume (terminal area) larger than the other portions, and the volume of the upper flow path of the body portion constituting the inflow bypass flow path is larger than other portions (terminal area) The resistance is reduced and the noise generation is reduced.

1 is a plan view showing an example of a general ventilator;
FIG. 2 is a plan view showing an embodiment of a ventilating apparatus according to the present invention,
FIG. 3 is a front view showing an embodiment of a ventilator having a bypass function according to the present invention. FIG.
FIG. 4 is a plan view showing a first embodiment of a bypass member constituting an embodiment of a ventilating apparatus according to the present invention,
5 is a front view showing a first embodiment of a bypass member constituting an embodiment of a ventilating apparatus according to the present invention,
FIG. 6 is a right side view showing a first embodiment of a bypass member constituting an embodiment of a ventilating apparatus according to the present invention,
7 is a plan view showing a second embodiment of a bypass member constituting an embodiment of a ventilating apparatus according to the present invention,
FIG. 8 is a perspective view showing a second embodiment of a bypass member constituting an embodiment of a ventilating apparatus according to the present invention,
9 is a perspective view showing crossed grooves of a second embodiment of a bypass member constituting an embodiment of a ventilation device according to the present invention,
10 is a plan view of a bypass member according to a first embodiment of the present invention,
11 is a front view of the first embodiment of the bypass member showing the operating state of the ventilator according to the present invention,
FIG. 12 is a right side view of a first embodiment of a bypass member showing an operating state of a ventilator according to the present invention. FIG.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a bypass member and a ventilator including the same according to the present invention will be described with reference to the accompanying drawings.

2 is a plan view showing an embodiment of a bypass member and a ventilator having the bypass member according to the present invention. 3 is a front view showing an embodiment of a bypass member and a ventilator having the bypass member according to the present invention.

2 and 3, an embodiment of the bypass member and the ventilator including the same according to the present invention includes the casing 100, the total enthalpy heat exchanger 300, the bypass member 400, the first damper 510), and a second damper (520).

The casing 100 is provided with an inflow passage P1 for guiding the outdoor air into the room and a discharge passage P2 for guiding the indoor air to be discharged outdoors. The casing 100 includes a front plate 110, a rear plate 120, a left plate 130, and a right plate 140 having a rectangular parallelepiped shape, And upper and lower plates 150 and 160 that cover the upper and lower ends of the front, rear, left and right plates 110, 120, 130 and 140 to form an inner space. The front, rear, left, and right positions of the casing 100 are set based on FIGS. 2 and 3 for convenience of explanation. Two through holes 131, 132, 141 and 142 are provided in the left plate 130 and the right plate 140, respectively. The two through holes of the left and right side plates 130 and 140 are referred to as first and second through holes 131 and 132 and 141 and 142, The second through hole 132 of the left side plate 130 and the second through hole 142 of the right side plate 140 are positioned such that the first through hole 141 of the left side plate 130 and the first through hole 141 of the right side plate 140 are opposed to each other, They are positioned facing each other. The inlet passage P1 is formed to communicate with the first through hole 131 of the left side plate 130 and the second through hole 142 of the right side plate 140. The discharge passage P2 is formed to communicate with the left side plate 130, And the first through hole 141 of the right side plate 140 are formed to communicate with each other.

The total enthalpy heat exchanger 300 is installed in the casing so that the inflow passage P1 and the discharge passage P2 are connected to each other so that the outdoor air flowing into the inflow passage P1 and the indoor air discharged into the discharge passage P2 are heat- . The total enthalpy heat exchanger 300 preferably has a hexahedral shape. The total enthalpy heat exchanger 300 is installed in the inner space of the casing 100 such that the four corners are positioned at the middle portions of the front, back, left and right plates 110, 120, 130 and 140 of the casing 100, Respectively.

As the total enthalpy heat exchanger 300 is positioned in the interior space of the casing 100, four compartment spaces S1, S2, S3, and S4 are formed in the casing 100. That is, the two compartment spaces S1 and S2 are located on the left side plate 130 side of the casing 100, which is one side of the total enthalpy heat exchanger 300, and the right side plate (not shown) of the casing 100, 140, two compartment spaces S3 and S4 are located. The two compartment spaces S1 and S2 positioned on the left side plate 130 side of the casing 100 are referred to as a first compartment space S1 and a second compartment space S2, S2 communicate with the first and second through holes 131, 132 of the left side plate 130, respectively. The two compartment spaces S3 and S4 located on the right side plate 140 side of the casing 100 may be referred to as a third and fourth compartment spaces S3 and S4. And communicates with the first and second through holes 141 and 142 of the right side plate 140. The first and fourth partition spaces S1 and S4 located in the diagonal direction among the four compartment spaces S1, S3, S3 and S4 constitute the inflow passage P1, , And the three compartment spaces S2 and S3 constitute the discharge passage P2. It is preferable that the lower plate 160 of the casing 100 is provided with an insertion hole for inserting the total enthalpy heat exchanger 300 and the lower plate 160 is provided with a plunger (not shown) for opening and closing the insertion hole.

The exhaust fan motor 810 is provided in the partition space S2 communicating with the left plate second through hole 132 of the casing 100 and communicated with the right plate second through hole 142 of the casing 100 And the intake fan motor 820 is provided in the partition space S3. The inlet duct 610 communicating with the outdoor side is connected to the first through hole 131 of the left side plate 130 of the casing 100 and the second through hole 132 of the left side plate 130 is connected to the outdoor side The exhaust duct 620 is connected to the exhaust duct 620. Closing dampers D for opening and closing the flow passages are provided on the side of the exhaust duct 620 and the side of the inlet duct 610, respectively.

The air exhaust pipe line 210 communicating with the indoor side is connected to the first through hole 141 of the right side plate 140 of the casing 100 and the second through hole 142 of the right side plate 140 is connected to the first through hole 141 of the right side plate 140 of the casing 100, An air inlet pipe line 220 communicating with the indoor side is connected to the air inlet pipe line.

The bypass member 400 is provided on the outer side of the casing and includes an exhaust bypass passage B2 for guiding the room air discharged through the exhaust passage P2 to pass through the exhaust passage P2 without passing through the total enthalpy heat exchanger 300 And an inflow bypass flow path B1 for guiding the outdoor air flowing through the inflow path P1 to pass through the inflow path P1 without passing through the total enthalpy heat exchanger.

4, 5, and 6, the first embodiment of the bypass member 400 includes a body portion 410 having an inner space, A partition wall portion 413 for partitioning the inner space of the lower flow path 412 into an upper flow path 411 and a lower flow path 412, A second lower duct portion 415 for communicating the other side of the lower flow path 412 with the other side of the discharge flow path P2 and a second lower duct portion 415 connecting one side of the upper flow path 411 and one side of the inflow path P1, And a second upper duct part 417 communicating the other side of the upper flow path 411 and the other side of the inflow path P1. The upper and lower surfaces of the body 410 are octagonal plates, and the side surfaces of the body 410 are formed into octagonal cylinders in which eight rectangular plates are continuously connected.

The partition wall 413 for heat exchange is preferably formed as an octagonal plate such as an upper surface and a lower surface of the body portion 410 and is preferably located at an intermediate portion in the longitudinal direction of the body portion 410. As another example of the body part 410, the body part 410 may be formed in a hexagonal tube shape, a rectangular tube shape, or a cylindrical shape with the upper and lower surfaces closed. Preferably, the first and second lower duct portions 414 and 415 are formed in a substantially rectangular tube shape, and that the first and second upper duct portions 416 and 417 are formed in a substantially curved rectangular tube shape Do. The first and second lower duct portions 414 and 415 are located on the same line and the first and second upper duct portions 416 and 417 are located on the same line. 415 and the first and second upper duct portions 416, 417 coincide with each other when viewed in a plan view. The bypass member 400 is preferably mounted on the upper surface of the casing 100 and the lower flow path 412 of the body portion 410 of the bypass member 400 and the first and second lower duct portions 414 415 constitute the discharge bypass flow passage B2 and the upper flow passage 411 and the first and second upper duct portions 416 417 of the body portion 410 constitute the inlet bypass flow passage B1 . The first and second lower duct portions 414 and 415 are respectively connected to the second and third compartment spaces S2 and S3 of the casing 100 with the bypass member 400 mounted on the upper surface of the casing 100, And the first and second upper duct portions 416 and 417 are connected to the casing 100 so as to communicate with the first and fourth compartment spaces S1 and S4 of the casing 100, Lt; / RTI >

The volume (the terminal area) of the lower flow path 411 of the body portion 410 constituting the discharge bypass flow path B2 is different from the volume of the other portions of the first and second lower duct portions 414 and 415 416 and 417 which are larger than the volume of the upper flow path 412 of the body portion 410 constituting the inflow bypass flow path B1, that is, the first and second upper duct portions 416 and 417, Is larger than each volume (terminal area).

When the bypass member 400 is mounted to the casing 100, the first and second lower duct portions 414 and 415 are respectively connected to the bypass member 400 and the casing 100 in a state where the bypass member 400 is mounted on the upper surface of the casing 100 The first and second upper ducts 416 and 417 are connected to the casing 100 so as to communicate with the first and fourth compartment spaces S1 and S4 of the casing 100, And may be connected to the casing 100 so as to communicate with the compartment spaces S2 and S3, respectively.

The first damper 510 opens and closes the discharge bypass flow passage B2. When the first damper 510 blocks the discharge bypass passage B2, exhaust air discharged to the outside is discharged through the discharge passage P2 and the total enthalpy heat exchanger 300, and the first damper 510 is discharged through the discharge bypass When the flow path B2 is opened, exhaust air is discharged through the discharge bypass flow path B2 by the flow path resistance of the total enthalpy heat exchanger 300. [ The first damper 510 may be mounted on the second lower duct portion 415 of the bypass member 400 to open and close the second lower duct portion 415.

The second damper 520 opens and closes the inflow bypass flow path B1. When the second damper 520 blocks the inflow bypass flow path B1, the inflow air flowing into the room flows into the inflow path P1 and the total enthalpy heat exchanger 300, and the second damper 520 flows into the inflow bypass When the flow path B1 is opened, the inflow air flows into the flow path of the total enthalpy heat exchanger 300 through the inflow bypass flow path B1. The second damper 520 may be mounted on the first upper duct portion 416 of the bypass member 400 to open or close the first upper duct portion 416.

7, 8, and 9, the second embodiment of the bypass member 400 is disposed on both sides of the total enthalpy heat exchanger 300, First and second discharge cap portions 430 and 440 coupled to the outer surface of the casing 100 so as to communicate with the first and second discharge cap portions 430 and 430, The first and second inflow cap ducts 450 and 450 are disposed on both sides of the total enthalpy heat exchanger 300 and are connected to the outer surface of the casing 100 so as to communicate with the inflow passage P1. And an inflow bypass duct part 480 located on the outer surface of the casing 100 and communicating with the first and second inflow cap parts 460 and 470. The first and second discharge cap portions 430 and 440 and the discharge bypass duct portion 450 form the discharge bypass flow passage B2 and the first and second inflow cap portions 460 and 470, Portion 480 forms the inflow bypass flow path B1. The first discharge cap portion 430 is communicated with the second compartment space S2 and the second discharge cap portion 440 is communicated with the third compartment space S3. The first inflow cap portion 460 communicates with the first compartment space S1 and the second inflow cap portion 470 communicates with the fourth compartment space S4.

The first and second discharge cap portions 430 and 440 and the first and second inflow cap portions 460 and 470 are formed in the shape of a cylinder with a top surface blocked, and the discharge bypass duct portion 450 and the inflow bypass duct portion (480) are each a rectangular tube having a rectangular cross section. Both ends of the discharge bypass duct part 450 are respectively connected to the outer peripheral surfaces of the first and second discharge cap parts 430 and 440. Both ends of the inflow bypass duct part 480 are connected to the first and second inflow cap parts 460) 470, respectively.

As shown in FIG. 9, the discharge bypass duct portion 450 and the inflow bypass duct portion 480 intersect with each other. In the discharge bypass duct portion 450, an intersecting groove 451 is provided on one side of the discharge bypass duct portion 450 An intersecting groove 481 is formed at a lower side of the inflow bypass duct portion 480 so that the intersection groove 451 of the discharge bypass duct portion 450 and the intersecting groove 481 of the inflow bypass duct portion 480, It is preferable that they intersect with each other. The thickness of the discharge bypass duct portion 450 and the inlet bypass duct portion 480 are preferably equal to each other and the depth of the cross groove 451 of the discharge bypass duct portion 450 is 1/2 of the thickness, The depth of the intersecting groove 481 of the pass duct portion 480 is preferably 1/2 of the thickness. As the exhaust bypass duct portion 450 and the inflow bypass duct portion 480 intersect with each other, the indoor air flowing into the discharge bypass duct portion 450 and the outdoor air flowing into the inflow bypass duct portion 480 Heat exchange can be efficiently performed.

Hereinafter, the operation and effect of the ventilator having the bypass function according to the present invention will be described.

First, when a room of a building equipped with a ventilation system is ventilated during a winter season or a summer season in which indoor and outdoor temperature differences are large, an opening / closing damper D provided in each of the inlet duct 610 and the outlet duct 620 is opened The exhaust fan motor 810 and the intake fan motor 820 are operated in a state in which the first damper 510 of the discharge bypass flow path B2 and the second damper 520 of the inlet bypass flow path B1 are closed The outside air flowing into the inflow duct 610 is supplied to the room through the inflow channel P1 of the casing 100 and the total enthalpy heat exchanger 300 through the air inflow pipe line 220, Air is discharged to the outside through the air discharge pipe line 210, the discharge passage P2 of the casing 100, the total heat exchanger 300, and the discharge duct 620. [ At this time, since the discharge bypass flow passage B2 and the inlet bypass flow passage B1 are blocked by the first damper 510 and the second damper 520, the discharge bypass flow passage B2 and the inlet bypass flow passage B1 The air will not flow.

The outdoor air flowing into the inflow channel P1 of the casing 100 and the indoor air discharged into the outflow channel P2 are exchanged with each other while passing through the total enthalpy heat exchanger 300, And the heat loss of the room is reduced.

On the other hand, when the temperature difference between the indoor and the outdoor is not large, the opening / closing damper D provided in the inlet duct 610 and the outlet duct 620 are opened and the first damper 10, 11, and 12 (12), when the exhaust fan motor 810 and the intake fan motor 820 are operated in a state in which the first damper 510 of the inlet bypass flow path B1 and the second damper 520 of the inlet bypass flow path B1 are respectively opened The outdoor air flowing into the inlet duct 610 flows into the inlet flow path P1 of the casing 100 and the inlet bypass flow B1 of the bypass member 400 without passing through the total enthalpy heat exchanger 300, The air is supplied to the room through the air inflow pipe line 220 and the air in the room is supplied to the air discharge pipe line 210, the outflow passage P2 of the casing 100, and the discharge bypass of the bypass member 400 The air is exhausted to the outside through the exhaust duct 620 through the flow path B2 and the air in the room is not passed through the total enthalpy heat exchanger 300. [

The operation of the exhaust fan motor 810 and the intake fan motor 820 is stopped when the indoor ventilation of the building is stopped and the opening and closing damper D provided in the inlet duct 610 and the outlet duct 620, Lt; / RTI >

As described above, the heat exchange between the outdoor air flowing into the indoor space through the total enthalpy heat exchanger (300) and the indoor air discharged into the outdoor space is effectively minimized in the winter season or the summer season when the temperature difference between indoor and outdoor is great, Not only the cold air or the hot air will flow into the room, but also maintain a comfortable indoor condition. In the spring or autumn when the temperature difference between the indoor and the outdoor is not large, the outdoor air flowing into the indoor space and the indoor air discharged to the outdoor are discharged through the inlet bypass flow line B1 and the discharge bypass flow line B2 So that the flow resistance of the air is reduced, thereby reducing the driving power of the motor and minimizing noise generation.

In the first embodiment of the bypass member 400 of the present invention, the outdoor air flowing into the room flows through the inflow bypass flow path B1, and the room air discharged to the outside flows through the discharge bypass flow path B2. The heat of the room air is transferred to the outdoor air through the partition wall 413 for partitioning the upper flow path 411 and the lower flow path 412 of the body part 410 in the process of flowing through the indoor space and the outdoor space, Even if the car is not large, the heat loss in the room is minimized. The lower flow path 412 of the body portion 410 constituting the discharge bypass flow path B2 has a volume (terminal area) larger than that of the other portions and is smaller than that of the body portion 410 constituting the inflow bypass flow path B1 The volume of the upper flow path 411 is larger than that of other portions (terminal area), thereby reducing the flow resistance of the air, thereby reducing noise generation.

In the second embodiment of the bypass member of the present invention, the outdoor air flowing into the room flows through the inflow bypass flow path B1, and the indoor air discharged to the outside flows through the discharge bypass flow path B2 The heat of the room air is transferred to the outdoor air in the intersection groove 451 of the discharge bypass duct part 450 and the intersection groove 481 of the inflow bypass duct part 480 so that the temperature difference between the room and the outside is large The heat loss in the room is minimized.

100; A casing 300; Total heat exchanger
400; A bypass member 510; The first damper
520; The second damper

Claims (2)

A casing having an inflow channel for guiding outdoor air into the room and a discharge channel for guiding indoor air to be discharged outdoors;
A total enthalpy heat exchanger mounted in the casing so that the inflow passage and the discharge passage are connected to each other, the indoor heat exchanger exchanging the outdoor air introduced into the inflow passage and the indoor air discharged into the discharge passage;
An exhaust bypass flow passage provided outside the casing for guiding indoor air discharged through the discharge flow passage to pass through the discharge flow passage without passing through the total enthalpy heat exchanger, A bypass member including an inlet bypass flow path for guiding the air to pass through the inflow passage without passing through an exchange;
A first damper for opening / closing the discharge bypass passage; And
And a second damper for opening and closing the inflow bypass flow path,
The bypass member includes first and second discharge cap portions that are respectively located on both sides of the total enthalpy heat exchanger and are coupled to the outer surface of the casing so as to communicate with the discharge flow passage, A first and a second inflow cap portions respectively disposed on both sides of the total enthalpy heat exchanger and connected to the outer side surface of the casing so as to communicate with the inflow passage; And an inflow bypass duct part for communicating the first and second inflow cap parts,
Wherein the first and second discharge cap portions and the discharge bypass duct portion form a discharge bypass flow passage, the first and second inlet cap portions and the inlet bypass duct portion form the inlet bypass flow passage,
Wherein the discharge bypass duct portion and the inlet bypass duct portion are square pipes each having a rectangular cross section,
Wherein the discharge bypass duct portion and the inlet bypass duct portion intersect with each other, wherein an intersecting groove is formed at an upper side of the discharge bypass duct portion and an intersecting groove is provided at a lower side of the inflow bypass duct portion, Wherein the cross groove and the cross groove of the inflow bypass duct portion are engaged with each other. The ventilating apparatus according to claim 1, wherein the first and second discharge cap portions and the first and second inflow cap portions are formed in a cylindrical shape with a top surface closed.

Images