KR102356237B1 - Vertical type dual ventilation apparatus - Google Patents

Abstract

The present invention relates to a standing dual ventilation apparatus. The standing dual ventilation apparatus comprises: a casing having a first and a second indoor air supply port separated from each other on the upper surface thereof, a first and a second indoor exhaust port on the front surface thereof, and a first and a second outdoor air supply port and an outdoor exhaust port on the rear surface thereof; a first and a second heat exchange element vertically inserted into both sides in the casing to heat-exchange indoor air and outdoor air; an air supply dual fan assembly provided on the upper side in the middle of the inside of the casing to be positioned between the first and second heat exchange elements, and generating a first air supply flow in which outdoor air is supplied to indoor space through the first outdoor air supply port, the first heat exchange element, and the first indoor air supply port, and a second air supply flow in which outdoor air is supplied to indoor space through the second outdoor air supply port, the second heat exchange element, and the second indoor air supply port; and an exhaust fan assembly provided on the lower side in the middle of the inside of the casing to be positioned between the first and second heat exchange elements, and generating a first exhaust flow in which indoor air is discharged to outdoor space through the first indoor exhaust port, the first heat exchange element, and the outdoor exhaust port, and a second exhaust flow in which indoor air is discharged to outdoor space through the second indoor exhaust port, the second heat exchange element, and the outdoor exhaust port. According to the present invention, indoor air is ventilated while the indoor air and outdoor air are heat-exchanged, and the flow loss of the indoor air and the outdoor air is reduced.

Description

VERTICAL TYPE DUAL VENTILATION APPARATUS

The present invention relates to a vertical dual ventilator.

In general, if a person is active indoors for a long time in a state where the indoor air is not well ventilated from the outside, it is difficult to maintain a comfortable state due to indoor air pollution and CO2 increase. Opening a window to ventilate not only introduces pollutants but also causes internal heat loss. A device to solve this problem is a ventilation system equipped with a total heat exchanger.

Republic of Korea Patent Publication No. 10-2019-0122074 (published on October 29, 2019) (hereinafter referred to as prior art) discloses an example of a ventilation system, a total heat exchanger installed on the wall of a building, and the total heat exchanger and the building An outdoor air inlet pipe that connects the indoor(s) of An indoor air exhaust pipe for guiding as much as possible is disclosed.

However, in the prior art, the total heat exchanger is installed on the wall of a building so that it communicates with the outdoors, and the outdoor air inlet pipe and indoor air exhaust pipe are installed in the total heat exchanger to connect indoors. There is a problem in that the flow loss is large.

It is an object of the present invention to provide a vertical dual ventilation device that ventilates indoor air while exchanging heat between indoor air and outdoor air, and reduces the flow loss between indoor air and outdoor air.

In order to achieve the above object, the first and second indoor air supply ports are provided on the upper surface at a distance from each other, the first and second indoor air exhaust ports are provided on the front side, and the first and second outdoor side air supply ports and the outdoor air outlet port are provided on the rear surface. a casing provided with a side exhaust port; first and second heat exchange elements inserted into both sides of the casing in a vertical direction to exchange heat between indoor air and outdoor air, respectively; It is provided in the upper middle of the inside of the casing so as to be located between the first and second heat exchange elements, and the outdoor air is supplied into the room through the first outdoor air supply port - the first heat exchange element - the first indoor air supply port. an air supply dual fan assembly for generating a first air supply flow and a second air supply flow in which outdoor air is supplied into the room through a second outdoor air supply port, a second heat exchange element, and a second indoor air supply port, respectively; A first exhaust flow provided at the lower middle of the inside of the casing so as to be located between the first and second heat exchange elements, and through which indoor air is exhausted to the outdoors through a first indoor exhaust port - a first heat exchange element - an outdoor exhaust port There is provided a vertical dual ventilation device including exhaust fan assemblies each generating a second exhaust flow in which air is exhausted to the outdoors through a second indoor exhaust port, a second heat exchange element, and an outdoor exhaust port.

The air supply dual fan assembly includes first and second support plates spaced apart from each other, and the first and second support plates positioned between the first and second support plates so that two motor shafts pass through the first and second support plates, respectively. A double-axis rotary motor fixed to the support plate, a first air supply fan coupled to the motor shaft of the double-axis rotary motor penetrating through the first support plate, and a second supply air coupled to the motor shaft of the dual-axis rotary motor penetrating through the second support plate It is preferred to include a fan.

Preferably, a flow mixing prevention plate is further provided to partition the space between the first and second support plates to separate the outdoor air flowing into the first air supply fan from the outdoor air flowing into the second air supply fan.

The exhaust fan assembly includes first and second support plates spaced apart from each other, a single-axis rotation motor fixed to the second support plate so that the motor shaft passes through the second support plate, and the first and second support plates positioned between the first and second support plates. It is preferable to include an exhaust fan coupled to the motor shaft of the single-axis rotation motor.

The exhaust fan assembly includes first and second support plates spaced apart from each other, and the first and second support plates positioned between the first and second support plates so that two motor shafts pass through the first and second support plates, respectively. A dual-axis rotary motor fixed to the, a first exhaust fan coupled to the motor shaft of the dual-axis rotary motor penetrated through the first support plate, and a second exhaust fan coupled to the motor shaft of the double-axis rotary motor penetrated through the second support plate may include

Preferably, a flow mixing prevention plate is further provided to partition a space between the first and second support plates to separate the outdoor air flowing into the first exhaust fan from the outdoor air flowing into the second exhaust fan.

According to the present invention, a casing having the first and second heat exchange elements, the air supply dual fan assembly and the exhaust fan assembly is installed indoors, and the first and second outdoor air supply ports and the outdoor exhaust ports of the casing are connected to the outside through a connecting pipe. As the flow path through which the indoor air is discharged to the outdoors and the path through which the outdoor air is supplied to the room are shortened, the flow loss between the indoor and outdoor air is reduced as well as the rotational motor driving power of the air supply dual fan assembly and the exhaust fan assembly. will decrease

In addition, since the air supply dual fan assembly of the present invention includes the first and second support plates, the double-axis rotary motor, and the first and second air supply fans, a single double-axis rotary motor drives the first and second air supply fans, so the configuration is compact Thus, the installation space is minimized and power consumption is reduced. In addition, when a flow mixing prevention plate is provided in the space between the first and second support plates, the space between the first and second support plates is partitioned to separate the outdoor air flowing into the first air supply fan from the outdoor air flowing into the second air supply fan. The flow loss due to mixing of the two outdoor air flows is reduced.

In addition, when the exhaust fan assembly of the present invention includes the first and second support plates, the double-axis rotary motor, and the first and second exhaust fans, the first and second exhaust fans are driven by a single double-axis rotary motor, so the configuration is compact Thus, the installation space is minimized and power consumption is reduced. In addition, when a flow mixing prevention plate is provided in the space between the first and second support plates, the space between the first and second support plates is partitioned to separate the indoor air exhausted by the first exhaust fan from the indoor air exhausted by the second exhaust fan. The flow loss due to mixing of the two room air flows is reduced.

1 is a perspective view showing an embodiment of a vertical dual ventilation device according to the present invention;
2 is a plan view showing an embodiment of a vertical dual ventilation device according to the present invention;
3 is a perspective view showing the inner front side of an embodiment of a vertical dual ventilation device according to the present invention;
4 is a perspective view showing the inner rear side of an embodiment of a vertical dual ventilation device according to the present invention;
5 is a front view showing an example of an air supply dual fan assembly and an exhaust fan assembly constituting an embodiment of the vertical dual ventilation device according to the present invention;
6 is a front view showing that a flow mixing prevention plate is provided in the exhaust fan assembly constituting an embodiment of the vertical dual ventilation device according to the present invention;
7 is a front view showing that a flow mixing prevention plate is provided in the exhaust fan assembly constituting an embodiment of the vertical dual ventilation device according to the present invention;
8 is a front view showing a second embodiment of an exhaust fan assembly constituting an embodiment of a vertical dual ventilation device according to the present invention;
9 is a cross-sectional view taken along the AA of FIG. 8;
10 is a front view showing another example of an outdoor exhaust port constituting an embodiment of the vertical dual ventilation device according to the present invention;
11 is a plan view showing the operating state of the vertical dual ventilation device according to the present invention.

Hereinafter, an embodiment of a vertical dual ventilation device according to the present invention will be described with reference to the accompanying drawings.

1 is a perspective view showing an embodiment of a vertical dual ventilation device according to the present invention. 2 is a plan view showing an embodiment of a vertical dual ventilation device according to the present invention. 3 is a perspective view showing the inner front side of an embodiment of the vertical dual ventilation device according to the present invention. 4 is a perspective view showing the inner rear side of an embodiment of the vertical dual ventilation device according to the present invention.

1, 2, 3, and 4, an embodiment of the vertical dual ventilation device according to the present invention includes a casing 100, first and second heat exchange elements 210 and 220, and an air supply dual fan assembly. 300 , and an exhaust fan assembly 400 .

The casing 100 is provided with first and second indoor air supply ports 101 and 102 spaced apart from each other on the upper surface, and the first and second indoor air exhaust ports 103 and 104 are provided on the front side, and at the rear surface. First and second outdoor air supply ports 105 and 106 and outdoor exhaust ports 107 are provided. As an example of the casing 100 , the casing 100 has an approximate hexahedral shape, the front 110 , the rear 120 , the left side 130 , the right side 140 , the upper surface 150 , the lower surface 160 ) includes The names of the front, rear, left, right, top, and bottom are set based on the front view, respectively. The first indoor air supply port 101 is provided on the left side 130 side of the upper surface 150 and the second indoor side air supply port 102 is provided on the right side 140 side. The first indoor exhaust port 103 is provided on the left side 130 side of the front side 110 and the second indoor side exhaust port 104 is provided on the right side 140 side. The first outdoor air inlet 105 is provided on the left side 130 of the rear side 120 , the second outdoor air supply port 106 is provided on the right side 140 , and the first and second outdoor air supply ports 105 are provided on the right side 140 . ) (106), an outdoor exhaust port (107) is provided. A flow path forming cover 170 is coupled to the rear surface 120 of the casing 100, and the flow path forming cover 1700 communicates with the first and second outdoor air supply ports 105 and 106 and the outdoor side exhaust port 107. First, second, and third flow paths may be formed.

The first and second heat exchange elements 210 and 220 are vertically inserted into both sides of the casing 100 to exchange heat between indoor air and outdoor air, respectively. The first heat exchange element 210 is formed in the form of a square column having a height corresponding to the inner height of the casing 100 and a square cross-section. The second heat exchange element 220 is preferably formed in the same size and shape as the first heat exchange element 210 . In the first and second heat exchange elements 210 and 220 , indoor air flows in front and rear directions, outdoor air flows in left and right directions, and indoor air and outdoor air exchange heat with each other while cross-flowing with each other. In the first heat exchange element 210 , outdoor air flows from the left surface 130 to the right surface 140 , and in the second heat exchange element 220 , outdoor air flows from the right surface 140 to the left surface 13 . . Preferably, a filter unit (F) for filtering outdoor air is provided on the left side of the first heat exchange element 210 and a filter unit (F) for filtering outdoor air is provided on the right side of the second heat exchange element (220). do.

The air supply dual fan assembly 300 is provided at the upper middle of the inside of the casing 100 so as to be positioned between the first and second heat exchange elements 210 and 220 . The air supply dual fan assembly 300 includes a first air supply flow in which outdoor air is supplied into the room through the first outdoor air supply port 105 - the first heat exchange element 210 - the first indoor air supply port 101; A second air supply flow is generated in which outdoor air is supplied into the room through the second outdoor air supply port 106 - the second heat exchange element 220 - and the second indoor air supply port 102, respectively.

As an example of the air supply dual fan assembly 300, as shown in FIGS. 3, 4 and 5, the air supply dual fan assembly 300 includes first and second support plates 310 and 320 located at a distance from each other and , located between the first and second support plates 310 and 320 and on the first and second support plates 310 and 320 so that two motor shafts penetrate the first and second support plates 310 and 320, respectively. The fixed double-axis rotary motor 330, the first air supply fan 340 coupled to the motor shaft of the double-axis rotary motor 330 penetrated through the first support plate 310, and the two shafts penetrated through the second support plate 320 and a second air supply fan 350 coupled to the motor shaft of the rotary motor 330 . The first support plate 310 is positioned on the side of the first heat exchange element 210 , and the second support plate 320 is positioned on the side of the second heat exchange element 220 . The first and second support plates 310 and 320 are provided with inlets through which air is introduced, respectively. The two-axis rotating motor 330 is provided with motor shafts on both sides of the motor body, and in a state where the two motor shafts penetrate the first and second support plates 310 and 320, both sides of the motor body have first and second support plates, respectively. It is fixed to (310) and (320). The first and second air supply fans 340 and 350 are preferably sirocco fans, respectively. The first air supply fan 340 is positioned between the first heat exchange element 210 and the first support plate 310 and is coupled to the motor shaft, and its discharge port 10 is directed toward the upper surface of the casing 100 and serves as the first indoor air supply. It is located in the instrument 101 . The second air supply fan 350 is positioned between the second heat exchange element 220 and the second support plate 320 and is coupled to the motor shaft, and its outlet 10 is directed toward the upper surface of the casing 100 and serves as a second indoor air supply. located on the instrument 102 .

In addition, as shown in FIG. 6 , the flow mixing prevention plate 360 is positioned between the first and second support plates 310 and 320 to partition the space between the first and second support plates 310 and 320 . It is preferable that this is provided. The flow mixing prevention plate 360 separates the outdoor air flowing into the first air supply fan 340 from the outdoor air flowing into the second air supply fan 350 .

In the air supply dual fan assembly 300 , as the double-axis rotation motor 330 operates, the rotational force is transmitted to the first and second air supply fans 340 and 350 through the two motor shafts, and the first and second air supply fans 340 . Each of the 350 is rotated to generate a flow. As the first and second air supply fans 340 and 350 rotate, respectively, the first outdoor air supply port 105 - the first heat exchange element 210 - the first air supply fan 340, in which the outdoor air is the first air supply passage - A second outdoor air supply port 106, which is a second air supply passage for outdoor air while supplying air to the room through the first indoor air supply port 101 - Second heat exchange element 220 - Second air supply fan 350 - Air is supplied into the room through the second indoor air inlet (102). That is, the first and second air supply fans 340 and 350 generate a first air supply flow to the first air supply passage and a second air flow to the second air supply passage at the same time. In the first supply air flow, outdoor air flows from the left to the right of the first heat exchange element 210, is sucked in from both suction ports of the first air supply fan 340, and is discharged through the discharge ports 10 located in the circumferential direction, In the secondary air flow, outdoor air flows from the right to the left of the second heat exchange element 220 , is sucked in from both suction ports of the second air supply fan 350 , and is discharged through the discharge ports 10 located in the circumferential direction. At this time, when the flow mixing prevention plate 360 is provided, the first air supply flow sucked into the inlet of the first air supply fan 340 and the second air flow sucked into the inlet of the second air supply fan 350 are mixed with each other. It prevents collision and flow resistance caused by the first and second supply air flow.

The exhaust fan assembly 400 is provided at the lower middle of the inside of the casing 100 so as to be positioned between the first and second heat exchange elements 210 and 220 . The exhaust fan assembly 400 includes a first exhaust flow in which indoor air is exhausted to the outside through the first indoor exhaust port 103 - the first heat exchange element 210 - the outdoor exhaust port 107, and the indoor air is The second exhaust flow exhausted to the outside through the indoor exhaust port 104 - the second heat exchange element 220 - the outdoor exhaust port 107 is generated, respectively.

As a first embodiment of the exhaust fan assembly 400, as shown in 3, 4, and 5, the exhaust fan assembly 400 includes first and second support plates 410 and 420 positioned at a distance from each other and , a single axis rotation motor 430 fixed to the second support plate 420 so that the motor shaft passes through the second support plate 420, and the single axis rotation motor 430 positioned between the first and second support plates 410 and 420 ( It includes an exhaust fan 440 coupled to the motor shaft of the 430). The first support plate 410 is positioned on the side of the first heat exchange element 210 and the second support plate 420 is positioned on the side of the second heat exchange element 220 . The first and second support plates 410 and 420 are provided with inlets through which air is introduced, respectively. The first and second support plates 410 and 420 of the exhaust fan assembly 400 are preferably positioned on the same vertical line as the first and second support plates 310 and 320 of the dual air supply fan assembly 300, respectively. The first and second support plates 410 and 420 of the exhaust fan assembly 400 may be formed integrally with the first and second support plates 310 and 320 of the dual air supply fan assembly 300, respectively. A partition plate dividing the inner space into upper and lower spaces between the first and second support plates 410 and 420 of the exhaust fan assembly 400 and the first and second support plates 310 and 320 of the dual air supply fan assembly 300 (180) is preferably provided. The dual air supply fan assembly 300 is positioned in the upper space, and the exhaust fan assembly 400 is positioned in the lower space. The single-axis rotation motor 430 is mounted on the second support plate 420 and the motor shaft is positioned between the first and second support plates 410 and 420 . The single-axis rotation motor 430 may be mounted on the first support plate 410 .

The exhaust fan 440 is preferably a sirocco fan. The discharge port 20 of the exhaust fan 440 is positioned toward the rear side of the casing 100 to communicate with the outdoor exhaust port 170 . Next to the first support plate 410 of the exhaust fan assembly 400 , a first flow path guide member 450 guiding indoor air passing through the front and rear directions of the first heat exchange element 210 to be introduced into one inlet of the exhaust fan 440 . ) is provided and a second flow path guide member 460 is provided next to the second support plate 420 to guide indoor air passing through the front and rear directions of the second heat exchange element 220 into the other suction port of the exhaust fan 440 . It is preferable to be provided.

In addition, as shown in FIGS. 6 and 7 , the exhaust partitioning the inner middle of the exhaust fan 440 and the middle of the outlet 20 so that the air sucked into both inlet ports of the exhaust fan 440 is not mixed with each other and discharged. It is preferable that the side flow mixing prevention plate (P) is provided.

In the first embodiment of the exhaust fan assembly 400 , as the single-axis rotation motor 430 operates, the rotational force is transmitted to the exhaust fan 440 through the motor shaft to generate a flow while the exhaust fan 440 rotates. As the exhaust fan 440 rotates, the first indoor exhaust port 103 through which the indoor air is the first exhaust passage - the first heat exchange element 210 - one inlet of the exhaust fan 440 - the outlet of the exhaust fan 440 (20) - the second indoor exhaust port 104, which is exhausted to the outside through the outdoor exhaust port 107, and at the same time, the indoor air is a second exhaust passage - the second heat exchange element 220 - the exhaust fan 440 The other inlet - the outlet 20 of the exhaust fan 440 - is exhausted to the outside through the outdoor exhaust port 107. That is, the exhaust fan 440 generates a first exhaust flow to the first exhaust passage and a second exhaust flow to the second exhaust passage. The first exhaust flow flows from the front surface (front surface of the casing) to the rear surface (rear surface of the casing) of the first heat exchange element 210 , and the second exhaust flow flows from the front surface (front surface of the casing) of the second heat exchange element 220 . It flows towards the rear (the rear of the casing). When the exhaust side flow mixing prevention plate (P) is provided, the air that is respectively sucked into both inlet ports of the exhaust fan 440 and exhausted to the outlet port 20 is mixed and prevented from collided with each other, thereby preventing the occurrence of exhaust flow resistance. .

As a second embodiment of the exhaust fan assembly 400 , as shown in FIGS. 8 and 9 , the exhaust fan assembly 400 includes first and second support plates 410 ′ and 420 ′ spaced apart from each other. and the first and second support plates 410' and 420' positioned between the first and second support plates 410' and 420' so that two motor shafts penetrate the first and second support plates 410' and 420', respectively. A first exhaust fan 480 coupled to the motor shaft of the double-axis rotary motor 470 fixed to the ') 420', and the double-axis rotary motor 470 penetrated through the first support plate 410', and the first 2 It includes a second exhaust fan 490 coupled to the motor shaft of the double-axis rotary motor 470 penetrated through the support plate 420'. The first support plate 410 ′ is positioned on the side of the first heat exchange element 210 , and the second support plate 420 ′ is positioned on the side of the second heat exchange element 220 . The first and second support plates 410' and 420' are provided with inlets through which air is introduced, respectively. Partitioning the inner space between the first and second support plates 410' and 420' of the exhaust fan assembly 400 and the first and second support plates 310 and 320 of the dual air supply fan assembly 300 into upper and lower spaces It is preferable that the partition plate 180 is provided. The dual air supply fan assembly 300 is positioned in the upper space, and the exhaust fan assembly 400 is positioned in the lower space. The two-axis rotating motor 470 is provided with motor shafts on both sides of the motor body, and both sides of the motor body are first, 2 is fixed to the support plates 410' and 420'. The first and second exhaust fans 480 and 490 are preferably sirocco fans, respectively. The first exhaust fan 480 is positioned between the first heat exchange element 210 and the first support plate 410 ′, is coupled to the motor shaft, and the outlet 21 is located on the rear surface 120 side of the casing 100 . . The second exhaust fan 490 is positioned between the second heat exchange element 220 and the second support plate 420 ′ and is coupled to the motor shaft, and its outlet 22 is located on the rear surface 120 side of the casing 100 . .

In addition, provided between the first and second support plates 410' and 420', the flow mixing prevention plate 360' that partitions the space between the first and second support plates 410' and 420' is provided. desirable. The flow mixing prevention plate 360 ′ separates the indoor air flowing into the first exhaust fan 480 from the indoor air flowing into the second exhaust fan 490 . The flow mixing prevention plate 360' is inside the flow mixing prevention plate 360' so that the body of the double-axis rotation motor 470 penetrates when dividing the space between the first and second support plates 410' and 420'. A motor through hole is provided.

In the case of the second embodiment of the exhaust fan assembly 400, as shown in FIG. 10, two outdoor exhaust ports 107' are provided on the rear surface 120 of the casing 100, and the two outdoor exhaust ports ( It is preferable that the outlets 21 and 22 of the first and second exhaust fans 480 and 490 communicate with each of the 107').

In the second embodiment of the exhaust fan assembly 400 , as the double-axis rotary motor 470 operates, its rotational force is transmitted to the first and second exhaust fans 480 and 490 through the two motor shafts to deliver the first and second exhaust As the fans 480 and 490 rotate, respectively, a flow is generated. As the first and second exhaust fans 480 and 490 rotate, respectively, the first indoor exhaust port 103 through which the indoor air is the first exhaust passage - the first heat exchange element 210 - the first exhaust fan 480 - The second indoor side exhaust port 104 - the second heat exchange element 220 - the second exhaust fan 490 - the outdoor which is exhausted to the outdoors through the outdoor exhaust port 107', and at the same time, the indoor air is a second exhaust passage It is exhausted to the outside through the side exhaust port 107'. That is, the first and second exhaust fans 480 and 490 generate a first exhaust flow to the first exhaust passage and a second exhaust flow to the second exhaust passage. The first exhaust flow flows from the front to the rear of the first heat exchange element 210 , and the second exhaust flow flows from the front to the rear of the second heat exchange element 220 . When the flow mixing prevention plate 360 ′ is provided, the first exhaust flow sucked into both inlets of the first exhaust fan 480 and the second exhaust flow sucked into both inlets of the second exhaust fan 490 are mixed with each other. In addition to preventing the air from being collided with each other, the discharge air discharged to the discharge port 107' is mixed and prevented from collided, thereby preventing flow resistance caused by the first and second exhaust flows.

Hereinafter, the operation and effect of the vertical dual ventilation device according to the present invention will be described.

First, when the concentration of carbon dioxide in the air inside the building increases to ventilate the indoor air, the air supply dual fan assembly 300 and the exhaust fan assembly 400 are operated, respectively. By the operation of the air supply dual fan assembly 300, as shown in FIG. 11, the outdoor air flows from the first outdoor air supply port 105 - the first heat exchange element 210 - the first air supply fan 340 - the second 1 Air is supplied to the room (L1) through the indoor air inlet 101, and at the same time, outdoor air is supplied through the second outdoor air inlet 106 - the second heat exchange element 220 - the second air supply fan 350 - the second indoor air. Air is supplied to the room (L2) through the side air supply port (102). At the same time, the indoor air is exhausted to the outside through the first indoor exhaust port 103 - the first heat exchange element 210 - the exhaust fan 440 - the outdoor exhaust port 107 by the operation of the exhaust fan assembly 400 At the same time (L3), indoor air is exhausted (L4) to the outside through the second indoor exhaust port 104 - the second heat exchange element 220 - the exhaust fan 440 - the outdoor exhaust port 107. As described above, the indoor air of the building is ventilated as the indoor air is exhausted to the outdoors and the outdoor air is supplied to the indoor space. In addition, indoor air and outdoor air of the building exchange heat with each other while passing through the first heat exchange element 210 , and indoor air and outdoor air exchange heat with each other while passing through the second heat exchange element 220 to reduce heat loss inside the building. while ventilating the indoor air of the building.

According to the present invention, the casing 100 having the first and second heat exchange elements 210 and 220 , the air supply dual fan assembly 300 , and the exhaust fan assembly 400 provided therein is installed indoors, and the casing 100 is manufactured. 1, 2 The outdoor air inlet 105, 106 and the outdoor air outlet 107 are communicated with the outdoors through a connecting pipe (not shown). As the flow path is shortened, the flow loss between the indoor air and the outdoor air is reduced, and the driving power of the rotary motor of the supply air dual fan assembly 300 and the exhaust fan assembly 400 is reduced.

In addition, the air supply dual fan assembly 300 of the present invention includes the first and second support plates 310 and 320 , the biaxial rotation motor 330 , and the first and second air supply fans 340 and 350 . Since the first and second air supply fans 340 and 350 are driven by the two-axis rotary motor 330, the configuration is compact, thereby minimizing the installation space and reducing power consumption. In addition, when the flow mixing prevention plate 360 is provided in the space between the first and second support plates 310 and 320, the space between the first and second support plates 310 and 320 is partitioned and the first air supply fan 340 is provided. ) and the outdoor air flowing into the second air supply fan 350 are separated to reduce flow loss due to mixing (collision) of the two outdoor air flows.

In addition, the exhaust fan assembly 400 of the present invention includes first and second support plates 410 ′ and 420 ′, a biaxial rotation motor 470 , and first and second exhaust fans 480 and 490 . In this case, since the first and second exhaust fans 480 and 490 are driven by a single double-axis rotary motor 470, the configuration is compact, thereby minimizing the installation space and reducing power consumption. In addition, when the flow mixing prevention plate 360' is provided in the space between the first and second support plates 410' and 420', the space between the first and second support plates 410' and 420' is divided to By separating the indoor air exhausted by the first exhaust fan 480 and the indoor air exhausted by the second exhaust fan 490, flow loss due to mixing of the two indoor air flows is reduced.

100; casing 210; first heat exchange element
220; a second heat exchange element 300; Air supply dual fan assembly
400; exhaust fan assembly

Claims (7)

a casing provided with first and second indoor air inlets at a distance from each other on an upper surface, first and second indoor exhaust ports on the front side, and first and second outdoor air supply ports and outdoor exhaust ports on the rear surface;
first and second heat exchange elements inserted in both sides of the casing in a vertical direction to exchange heat between indoor air and outdoor air, respectively;
It is provided in the upper middle of the inside of the casing so as to be located between the first and second heat exchange elements, and outdoor air is supplied into the room through the first outdoor air supply port - the first heat exchange element - the first indoor air supply port. an air supply dual fan assembly for generating a first air supply flow and a second air supply flow in which outdoor air is supplied into the room through the second outdoor air supply port, the second heat exchange element, and the second indoor air supply port, respectively;
A first exhaust flow provided at the lower middle of the inside of the casing so as to be located between the first and second heat exchange elements, and through which indoor air is exhausted to the outdoors through a first indoor exhaust port - a first heat exchange element - an outdoor exhaust port and an exhaust fan assembly for generating a second exhaust flow in which air is exhausted to the outdoors through a second indoor exhaust port, a second heat exchange element, and an outdoor exhaust port;
The air supply dual fan assembly includes first and second support plates spaced apart from each other, and the first and second support plates positioned between the first and second support plates so that two motor shafts pass through the first and second support plates, respectively. A double-axis rotary motor fixed to the support plate, a first air supply fan coupled to the motor shaft of the double-axis rotary motor penetrating through the first support plate, and a second supply air coupled to the motor shaft of the dual-axis rotary motor penetrating through the second support plate A flow mixing prevention plate that divides the space between the fan and the first and second support plates to separate the outdoor air flowing into the first air supply fan and the outdoor air flowing into the second air supply fan from mixing and collide with each other. Including vertical dual ventilation system. [2] The vertical dual ventilation system according to claim 1, wherein the first and second heat exchange elements are each formed in the form of a square column having a height corresponding to an inner height of the casing and a quadrangular cross-section. delete delete The method of claim 1, wherein the exhaust fan assembly includes first and second support plates spaced apart from each other, a single-axis rotation motor fixed to a second support plate so that a motor shaft passes through the second support plate, and the first and second support plates; A vertical dual ventilation device including an exhaust fan positioned between the support plates and coupled to the motor shaft of the single-axis rotary motor. The exhaust fan assembly of claim 1, wherein the exhaust fan assembly includes first and second support plates spaced apart from each other, and the first and second support plates positioned between the first and second support plates so that two motor shafts pass through the first and second support plates, respectively. A double-axis rotary motor fixed to the first and second support plates, a first exhaust fan coupled to a motor shaft of the double-axis rotary motor penetrating through the first support plate, and a motor shaft of the double-axis rotary motor penetrating through the second support plate A vertical dual ventilation system including a coupled second exhaust fan. The flow mixing prevention plate according to claim 6, further comprising: a flow mixing prevention plate partitioning a space between the first and second support plates to separate outdoor air flowing into the first exhaust fan and outdoor air flowing into the second exhaust fan. Vertical dual ventilation system with

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