KR100700191B1 - Ventilating apparatus - Google Patents

Abstract

The present invention discloses a ventilation device capable of performing dehumidification of air introduced from the outside while performing a ventilation function, and performing continuous dehumidification of indoor air only through circulation of indoor air without introducing external air. The disclosed ventilator includes a main body installed to connect the indoor and the outdoor; A total heat exchanger installed inside the main body; An air supply passage installed in the main body and configured to introduce outdoor air into the room through an electrothermal exchanger; An exhaust passage installed in the main body and configured to discharge indoor air to the outside through an electrothermal exchanger; A ventilator including a dehumidifying rotor having a dehumidifying unit and a regenerating unit, wherein the dehumidifying unit is positioned in the air supply passage downstream of the total heat exchanger, and the regeneration unit is positioned in the exhaust passage downstream of the total heat exchanger.

Description

Ventilation device {VENTILATING APPARATUS}

1 is a cross-sectional view showing the internal configuration of the ventilation apparatus according to the first embodiment of the present invention, showing a state in which ventilation and dehumidification is performed.

Figure 2 is a perspective view showing the configuration of the dehumidification rotor of the ventilation apparatus according to the first embodiment of the present invention.

3 is a cross-sectional view taken along line III-III ′ of FIG. 2.

Figure 4 is a cross-sectional view showing the internal configuration of the ventilation apparatus according to the first embodiment of the present invention, showing a state in which dehumidification is performed without introducing the outside air.

5 is a cross-sectional view showing the internal configuration of the ventilation apparatus according to the first embodiment of the present invention, showing a state in which ventilation is performed without a dehumidification operation.

6 is a cross-sectional view showing the internal configuration of the ventilation apparatus according to the second embodiment of the present invention, which shows a state in which dehumidification is performed without introducing external air.

7 is a cross-sectional view showing the internal configuration of the ventilation apparatus according to the second embodiment of the present invention, showing a state in which ventilation and dehumidification is performed.

8 is a cross-sectional view showing the internal configuration of the ventilation apparatus according to the third embodiment of the present invention, showing a state in which ventilation and dehumidification is performed.

9 is a cross-sectional view showing the internal configuration of the ventilator according to the third embodiment of the present invention, which shows a state in which dehumidification is performed without introducing external air.

10 is a cross-sectional view showing the internal configuration of the ventilation apparatus according to the third embodiment of the present invention, showing a state in which ventilation is performed without a dehumidification operation.

11 is a cross-sectional view showing the internal configuration of the ventilation apparatus according to the fourth embodiment of the present invention, showing a state in which dehumidification is performed without introducing external air.

12 is a cross-sectional view showing the internal configuration of the ventilation apparatus according to the fourth embodiment of the present invention, showing a state in which ventilation and dehumidification are performed.

Explanation of symbols on the main parts of the drawings

10,100: main body, 11,110: indoor inlet,

12,120: indoor outlet, 13,130: outdoor inlet,

14,140: outdoor outlet, 15,150: partition plate,

20,200: total heat exchanger, 20a, 200a: first air passage,

20b, 200b: second air passage, 31,310: first air supply passage,

32,320: 2nd supply flow path, 33,330: 3rd supply flow path,

34,340: 1st blowing fan, 41,410: 1st exhaust flow path,

42,420: second exhaust euro, 43: third exhaust euro,

44,440: second blowing fan, 50,500: dehumidification rotor,

60,70,600,700: bypass flow path, 61,71,610,710: bypass damper,

62,620: outdoor inlet damper, 63,630: dehumidification damper,

64,640: regenerative damper, 65,650: outdoor outlet damper,

430: Communicate Euro.

The present invention relates to a ventilator, and more particularly, to a ventilator that can perform both dehumidification and dehumidification together, and to perform dehumidification only through circulation of indoor air without introducing an outside air.

Japanese Patent Laid-Open No. 8-94124 discloses a ventilator employing an electrothermal exchanger. The ventilator is provided with an indoor inlet and an outdoor outlet on the indoor side, an outdoor inlet and an outdoor outlet on the outdoor side, an electric heat exchanger installed inside the main body, and an inlet and an outdoor inlet inside the body, respectively. Blowers, heaters for heating indoor air and outdoor air, respectively, and flow paths for varying the flow path inside the main body are provided.

This ventilator operates the variable flow path so that outdoor air enters the room and indoor air is discharged to the outside when the ventilation operation is performed. In addition, when dehumidifying and humidifying the indoor air, the flow path is introduced from the room by the variable stage operation, and the indoor air passing through the heat exchanger is discharged back to the indoor space. In addition, when performing heat regeneration in the process of performing dehumidification and humidification of indoor air, outdoor air introduced from the outside and passed through the heat exchanger is discharged back to the outside.

However, such a ventilator has a problem in that continuous dehumidification operation is impossible because indoor air is discharged back to the room through the heat exchanger or outdoor air is discharged back to the outside through the heat exchanger. there was.

In addition, this ventilator was dehumidified by using a total heat exchanger because of the long operation time of the equipment, which resulted in a high energy cost and operation noise and a low dehumidification effect.

In addition, this ventilation device has a problem that can not perform the ventilation of the room during the dehumidification operation.

The present invention is to solve such a problem, it is an object of the present invention to provide a ventilation device to perform the dehumidification of the air flowing from the outside while performing the ventilation function.

Another object of the present invention is to provide a ventilation device to enable continuous dehumidification of indoor air only through circulation of indoor air without introducing external air, and to improve the dehumidification effect compared to the prior art.

Ventilation apparatus according to the present invention for achieving this object and the main body is installed to connect the indoor and outdoor; A total heat exchanger installed inside the main body; An air supply passage installed in the main body and introducing outdoor air into the room via the heat exchanger; An exhaust passage installed in the main body and configured to discharge indoor air to the outside through the heat exchanger; A ventilation device comprising a dehumidification rotor having a dehumidifying part and a regenerating part, wherein the dehumidifying part is located in the air supply passage downstream of the heat exchanger, and the regeneration part is installed in the exhaust flow path downstream of the heat exchanger. do.
In addition, the present invention further comprises a dehumidification damper for bypassing the dehumidifying part of the dehumidification rotor to communicate with the room downstream of the air supply passage and a regeneration damper for bypassing the regeneration part of the dehumidification rotor to communicate with the outdoors downstream of the exhaust passage. It is characterized by including.
In addition, the present invention is characterized in that when the ventilation device is to operate in the ventilation mode, the dehumidification damper and the regeneration damper is opened, so that intake and exhaust are performed through the open dampers.
In addition, the present invention, when the ventilation device is to operate in the ventilation and dehumidification mode, the dehumidification damper is closed so that the air supply passage is sucked through the dehumidification part of the dehumidification rotor, and the regeneration damper is partially opened so that part of the exhaust passage Passing through the regeneration unit of the dehumidification rotor, and part of the through the regeneration damper is characterized in that the discharge to the outdoors.
In addition, the ventilation device according to the present invention and the main body is installed to connect the indoor and outdoor; A total heat exchanger installed inside the main body; An air supply passage installed in the main body and introducing outdoor air into the room via the heat exchanger; An exhaust passage installed in the main body and configured to discharge indoor air to the outside through the heat exchanger; A ventilator including a dehumidification rotor having a dehumidifying unit and a regenerating unit, wherein the dehumidifying unit is positioned in the air supply passage downstream of the heat exchanger, and the regeneration unit is located in the exhaust passage downstream of the heat exchanger, An upstream side of the flow passage is provided with a bypass flow passage that bypasses the heat exchanger and communicates with the air supply flow passage.
In addition, the bypass passage is characterized in that it comprises a damper for selectively opening and closing the bypass passage.
In addition, the bypass passage is characterized in that it is formed so as to communicate with the upstream side of the exhaust passage and the upstream side of the air supply passage before passing through the heat exchanger.
In addition, when the ventilator is intended to operate in the dehumidification mode, the damper of the bypass passage on the exhaust passage is opened so that some of the exhaust passage bypasses the heat exchanger and passes the dehumidifying part of the heat exchanger and the dehumidification rotor through the intake passage. It is to be sucked into the room, and some of the exhaust passage is characterized in that the discharge through the regeneration unit of the total heat exchanger and dehumidification rotor to the outside.
In addition, the bypass passage is characterized in that it is formed so as to communicate with the air supply passage after passing through the upstream side of the exhaust passage and the heat exchanger.
Also, when the ventilator is to operate in the dehumidification mode, the damper of the bypass passage on the exhaust passage is opened so that some of the exhaust passage bypasses the heat exchanger, passes through the air supply passage, and passes the dehumidification part of the dehumidification rotor to the room. It is to be sucked, and some of the exhaust flow passage is characterized in that the discharge through the regeneration unit of the heat exchanger and the dehumidification rotor to the outside.
In addition, the present invention and the main body is installed to connect the indoor and outdoor; A total heat exchanger installed inside the main body; An air supply passage installed in the main body and introducing outdoor air into the room via the heat exchanger; An exhaust passage installed in the main body and configured to discharge indoor air to the outside through the heat exchanger; A ventilation device comprising a dehumidification rotor having a dehumidification part and a regeneration part, wherein the dehumidification part of the dehumidification rotor is disposed in the air supply passage downstream of the heat exchanger and is installed to communicate with a room, and the regeneration part of the dehumidification rotor is installed in the heat exchanger. It is characterized in that it is disposed in the downstream air supply passage and installed to communicate with the outdoors.
In addition, the present invention is characterized in that the partition plate for partitioning the indoor side and the outdoor side is installed downstream of the air supply passage in which the dehumidification rotor is installed, the dehumidification rotor is installed on the partition plate.
In another aspect, the present invention is characterized by further comprising a dehumidification damper for bypassing the dehumidifying part of the dehumidifying rotor to communicate with the room downstream and the regeneration damper for opening and closing the regeneration unit of the dehumidifying rotor communicating with the outdoor side. .
In addition, when the ventilation device is to operate in the ventilation mode, the dehumidification damper is opened and the regenerative damper is closed, and the air supply passage bypasses the dehumidification part of the dehumidification rotor and is taken into the room, and the indoor air is exhausted through the exhaust passage. It is characterized in that the exhaust to the outside.
In addition, when the ventilation device is to operate in the ventilation and dehumidification mode, the dehumidification damper is closed, the regeneration damper is opened, and a part of the air supply passage is sucked through the dehumidification part of the dehumidification rotor, and the Some are characterized in that the discharge through the regeneration unit of the dehumidification rotor to the outside.
In addition, the ventilation device according to the present invention and the main body is installed to connect the indoor and outdoor; A total heat exchanger installed inside the main body; An air supply passage installed in the main body and introducing outdoor air into the room via the heat exchanger; An exhaust passage installed in the main body and configured to discharge indoor air to the outside through the heat exchanger; A ventilation device comprising a dehumidification rotor having a dehumidification part and a regeneration part, wherein the dehumidification part of the dehumidification rotor is disposed in the air supply passage downstream of the heat exchanger and is installed to communicate with a room, and the regeneration part of the dehumidification rotor is installed in the heat exchanger. It is disposed in the air supply passage downstream and installed to communicate with the outside, characterized in that the upstream side of the exhaust flow passage is provided with a bypass flow passage for communicating with the air supply passage by bypassing the total heat exchanger.
In addition, the bypass passage is characterized in that it comprises a damper for selectively opening and closing the bypass passage.
In addition, the bypass passage is characterized in that it is formed so as to communicate with the upstream side of the exhaust passage and the upstream side of the air supply passage before passing through the heat exchanger.
When the ventilation device is to operate in the dehumidification mode, the damper of the bypass passage on the exhaust passage is opened so that all of the exhaust passage bypasses the heat exchanger and passes through the air supply passage and the heat exchanger, and part of the exhaust passage is the dehumidification rotor. After passing through the dehumidifying unit of the indoor suction, some of the exhaust passage is characterized in that the discharge through the regeneration unit of the dehumidification rotor to the outside.
In addition, the bypass passage is characterized in that it is formed so as to communicate with the air supply passage after passing through the upstream side of the exhaust passage and the heat exchanger.
According to the present invention, when the ventilation device is to operate in the dehumidification mode, the damper of the bypass passage on the exhaust passage is opened so that all of the exhaust passage bypasses the heat exchanger and passes through the air supply passage, and part of the exhaust passage is Pass through the dehumidifying part of the dehumidification rotor to be sucked into the room, and part of the exhaust passage is characterized in that the discharge through the regeneration unit of the dehumidification rotor to the outside.

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

1 to 5 show a first embodiment of the ventilation device according to the present invention. As shown in FIG. 1, the ventilator of the first embodiment includes an indoor inlet 11 and an indoor outlet 12 formed in an indoor side of a main body 10 in a rectangular box shape. An outdoor inlet 13 and an outdoor outlet 14 formed on the outdoor side are provided.

The inside of the main body 10 is provided with a total heat exchanger 20 for heat exchange between the air introduced from the outside and the air discharged from the room. As for the total heat exchanger 20, the first side 21 and the second side 22, which face each other, communicate with each other through the first air passage 20a and also face each other, similarly to the conventional heat exchanger 20. The third side surface 23 and the fourth side surface 24 communicate with each other through the second air passage 20b partitioned from the first air passage 20a. This allows the indoor air and the outdoor air to exchange heat while passing through the first air passage 20a and the second air passage 20b of the total heat exchanger 20.                     

In addition, the inside of the main body 10 to discharge the outdoor air introduced through the outdoor inlet 13 for the ventilation of the indoor space through the first air passage (20a) of the total heat exchanger (20) to the indoor outlet (12). An air supply passage and an exhaust passage through which the indoor air introduced through the indoor inlet 11 is discharged to the outdoor discharge port 14 through the second air passage 20b of the total heat exchanger 20 are provided.

The air supply passage passes air through the first air passage 31 and the first air passage 20a of the heat exchanger 20, which are formed so that the outdoor inlet 13 and the inlet of the first air passage 20a of the heat exchanger communicate with each other. It includes a second air supply flow path 32 made of a space for receiving, and the third air supply flow path 33 formed to communicate the second air supply flow path 32 and the indoor discharge port (12). That is, the outdoor air passage passes through the first air passage 31, the first air passage 20a of the total heat exchanger, the second air passage 32, the third air passage 33, and the indoor outlet 12 in order. Allow it to enter the indoor space. In addition, a first blowing fan 34 is installed in the second air supply passage 32 to blow air through the air supply passage. In addition, for this blowing, the first blowing fan 34 is provided with a blowing case 34a whose outlet is connected to the inlet of the third air supply passage 33.

The exhaust flow path receives air passing through the first air flow passage 41 and the second air flow passage 20b of the heat exchanger, which are formed to communicate with the indoor inlet 11 and the inlet of the second air passage 20b of the heat exchanger. A second exhaust passage 42 formed of a space, and a third exhaust passage 43 for communicating the second exhaust passage 42 and the outdoor discharge port (14). Such exhaust passages include indoor air inlet 11, first exhaust passage 41, second air passage 20b of the total heat exchanger, second exhaust passage 42, third exhaust passage 43, and outdoor outlet. It is to be exhausted to the outdoor through (14) in order. In addition, a second blower fan 44 is installed inside the second exhaust passage 42 to blow air through the exhaust passage, and the second blower fan 44 has a third outlet at the outlet to enable such a blow. A blower case 44a connected to the inlet of the exhaust passage 43 is provided. In such a ventilation device, the flow paths inside the main body 10 are formed through a plurality of partition plates installed to partition the inside of the main body 10 as in the general ventilation device.

In addition, the third air supply passage 33 and the third exhaust passage 43 are divided by partition plates 15 partitioning between the two flow passages 33 and 43, as shown in Figs. The sections are adjacent to each other, and the partition plate 15 partitioning between the third air supply passage 33 and the third exhaust passage 43 is for dehumidifying air supplied to the indoor space, and includes a regeneration unit and a dehumidification unit. Dehumidification rotor 50 is installed.

2 and 3, the dehumidification rotor 50 is made of a rotating body coated with a moisture adsorbent on the surface of the lattice-shaped mesh or honeycomb-like surface which can distribute air. As the moisture adsorbent, a material having moisture adsorption such as silica gel or zeolite is used.

In addition, the dehumidification rotor 50 is located inside the third air supply passage 33 so as to contact the air supplied to the room through the third air supply passage 33 and the other side to the outside through the third exhaust passage 43. It is arrange | positioned so that it may be located in the 3rd exhaust flow path 43 so that it may contact with the air discharged, and the center is rotatably supported by the partition plate 15. As shown in FIG. In addition, the dehumidifying rotor 50 is rotated by the driving of the motor 51 installed in the third air supply passage 33, and the area exposed in the third air supply passage 33 is exposed in the third exhaust passage 43. It is made larger. To this end, as shown in FIG. 3, the partition plate 15 is provided with a bent portion 15a having a triangular cross section protruding toward the third air supply passage 33. In addition, a heater 53 for heating air flowing toward the dehumidification rotor 50 is installed at a position near the dehumidification rotor 50 at the inlet side of the third exhaust passage 43. The dehumidifying rotor 50 is a dehumidifying part for dehumidifying the air flowing into the room located in the third air supply passage 33, and the third exhaust path 34 is moistened by heating of the heater 53. Becomes a reproducing section from which is removed.

This configuration is such that dehumidification is achieved by adsorption of water while the air supplied to the room via the third air supply passage 33 passes through the dehumidification rotor 50 toward the third air supply passage 33. The moisture adsorbed to the dehumidification rotor 50 is removed in the process of passing the dehumidified rotor 50 through the dehumidification rotor 50 when the dehumidifying rotor 50 is rotated toward the third exhaust passage 43. It is to be discharged to the outside with the exhaust air. Therefore, the dehumidification rotor 50 is regenerated to absorb water again because water is removed from the third exhaust flow path 43, and rotates toward the third air supply flow path 33 to again the third air supply flow path 33. Dehumidification can be performed.

In addition, as shown in FIG. 4, the air of the first exhaust passage 41 is introduced into the first air supply passage 31 so that dehumidification can be performed through the circulation of indoor air without introducing external air. And a bypass passage 60 for opening and closing the bypass passage 60, a bypass damper 61 for opening and closing the bypass passage 60, and an outdoor inlet damper 62 for opening and closing the outdoor inlet 13.

In addition, a partition plate 35 is provided in the third air supply passage 33 to partition the inside of the third air supply passage 33 so that the air flowing into the third air supply passage 33 can be guided toward the dehumidification rotor 50. ) And a dehumidification damper 63 (dehumidification damper) for opening and closing the flow path in the space between the partition plate 16 on the side of the second air supply passage 32. This configuration is such that when the dehumidification damper 63 is opened, the air introduced into the third air supply passage 33 bypasses the dehumidification rotor 50 and flows toward the indoor outlet 12, and when the dehumidification damper 63 is closed, the third air supply is provided. All of the air introduced into the flow path 33 passes through the dehumidification rotor 50 to be dehumidified and then flows toward the indoor outlet 12.

In addition, a partition plate 45 for partitioning the inside of the third exhaust passage 43 so as to guide the air flowing into the third exhaust passage 43 toward the dehumidification rotor 50 is provided. ) And a regeneration damper 64 (regeneration damper) for opening and closing the flow passage in the space between the partition plate 17 of the second exhaust passage 42. This configuration is such that when the regenerative damper 64 is opened, the air introduced into the third exhaust passage 43 bypasses the dehumidifying rotor 50 and flows toward the outdoor outlet 14, and when the regenerative damper 64 is closed, the third exhaust. After the air introduced into the flow path 43 is heated through the heater 53, the air flows through the dehumidification rotor 50 and flows toward the outdoor discharge port 14.

The outdoor exhaust port 14 can be opened and closed according to the user's needs to prevent the backflow of outdoor air back into the main body 10 through the outdoor exhaust port 14 due to the stop of the operation of the ventilation device or severe draft. An outdoor outlet damper 65 is provided.

The operation of this ventilation device (first embodiment) is performed as follows.

When performing ventilation of indoor air and dehumidifying air introduced from the outside, as shown in FIG. 1, the bypass damper 61 and the dehumidification damper 63 are closed, and the outdoor inlet damper 62 and the outdoor outlet are closed. The damper 65 is opened, and the regeneration damper 64 is partially opened. In addition, the first and second blowing fans 34 and 44 operate, the heater 53 is driven, and the dehumidification rotor 50 rotates gradually.

When performing this operation, the outdoor air is the outdoor inlet 13, the first air supply passage 31, the first air passage 20a of the total heat exchanger, the second air supply passage 32, the first blowing fan 34, Through the third air supply passage 33, the dehumidification rotor 50 of the third air supply passage side, and the indoor discharge port 12 in order to flow into the indoor space. Therefore, the air introduced from the outside is supplied to the room after dehumidification.

The indoor air is provided with an indoor inlet 11, a first exhaust passage 41, a second air passage 20b of the total heat exchanger, a second exhaust passage 42, a second blowing fan 44, and a third exhaust passage ( 43), the heater 53, the dehumidification rotor 50 toward the third exhaust passage 43, and the outdoor discharge port 14 are sequentially discharged to the outside. In addition, a part of the air discharged through the third exhaust passage 43 is discharged to the outside in the state that does not pass through the dehumidification rotor 50 because the regeneration damper 64 is partially open. At this time, a part of the air discharged to the outside is heated by the heater 53 and then passes through the dehumidification rotor 50, so that the dehumidification rotor 50 is removed by removing moisture from the dehumidification rotor 50 toward the third exhaust passage 43. Play it back.

In addition, when such an operation is performed, the outdoor air and the indoor air cross the heat exchanger 20 so that heat exchange between the indoor air and the outdoor air is performed to reduce heat loss of the indoor space, and the air introduced from the outside is dehumidified. The primary dehumidification may be performed while passing through the total heat exchanger 20 capable of absorbing moisture before passing through the rotor 50. In addition, since the dehumidification rotor 50 rotates during the ventilation operation, continuous dehumidification of the air introduced into the room becomes possible.

When dehumidifying the indoor air without ventilating the indoor air (without introducing the outdoor air), the bypass damper 61 and the outdoor outlet damper 65 are opened, and the outdoor inlet damper 62 is opened as shown in FIG. The dehumidification damper 63 and the regeneration damper 64 operate to close the flow path. In addition, the first and second blowing fans 34 and 44 operate, the heater 53 is driven, and the dehumidification rotor 50 rotates gradually. In this case, the second blowing fan 44 rotates more slowly than the first blowing fan 34 so as to reduce the air discharged to the outside.

Most of the indoor air when the operation is made, the indoor inlet 11, the first exhaust passage 41, the bypass passage 60, the first air supply passage 31, the first air passage 20a of the total heat exchanger, The second air supply passage 32, the first blowing fan 34, the third air supply passage 33, the third air supply passage side dehumidification rotor 50, and then through the indoor outlet 12 is supplied to the interior space again. In this process, since all the air passing through the third air supply passage 33 passes through the dehumidification rotor 50, dehumidification of indoor air is performed.

In addition, a part of the indoor air introduced into the first exhaust passage 41 from the indoor inlet 11 is the second air passage 20b, the second exhaust passage 42, and the second blowing fan 44 of the total heat exchanger 20. ), The third exhaust passage 43, the heater 53, the third exhaust passage 43, the dehumidification rotor 50, and the outdoor discharge port 14 are sequentially discharged to the outside. At this time, the air discharged to the outside by the operation of the second blowing fan 43 is a small amount compared to the air circulating indoors because the second blowing fan 44 rotates at a low speed compared to the first blowing fan 34. In addition, since the air discharged to the outside passes through the dehumidification rotor 50 after being heated by the heater 53, the dehumidification rotor is regenerated.

When only the ventilation is performed without the dehumidification operation, as shown in FIG. 5, the bypass damper 61 is closed, and the outdoor inlet damper 62, the dehumidification damper 63, the regeneration damper 64, and the outdoor outlet damper 65 are closed. All open. Further, the first blowing fan 34 and the second blowing fan 44 operate, and the operation of the heater 53 and the dehumidification rotor 50 are stopped.

Therefore, the outdoor air is the outdoor air inlet 13, the first air supply passage 31, the first air passage 20a of the total heat exchanger 20, the second air supply passage 32, the first blowing fan 34, the third Through the air supply passage 33, the indoor discharge port 12 in order to flow into the indoor space. At this time, the air flowing into the indoor from the outside bypasses the dehumidification rotor 50 inside the third air supply passage 33 or only a part passes through the dehumidification rotor 50, and dehumidification because the rotation of the dehumidification rotor 50 is not made. This is not done. The indoor air is provided with an indoor inlet 11, a first exhaust passage 41, a second air passage 20b of the total heat exchanger, a second exhaust passage 42, a second blowing fan 44, and a third exhaust passage ( 43) through the outdoor discharge port 14 in order to be discharged to the outdoor. At this time, the air discharged to the outside is also discharged by bypassing the dehumidification rotor (50).

6 and 7 show a second embodiment of the ventilation device according to the present invention. The second embodiment is a bypass flow path 70 which can directly communicate the first exhaust flow path 41 and the second air supply flow path 32 in place of the bypass flow path 60 and the bypass damper 61 in the first embodiment. And, there is a difference from the first embodiment in that the bypass damper 71 that can open and close the bypass flow path 70 is provided. The rest of the configuration is the same as in the first embodiment.

When such a ventilation device performs dehumidification together with ventilation, as shown in FIG. 7, the bypass flow path 70 is closed by the bypass damper 71, and the rest operates in the same manner as the first embodiment. The same as the ventilation and dehumidification operation in the first embodiment. In addition, although not shown in the drawings, even when only the ventilation is performed without the dehumidification operation, the substantial flow is made in the same manner as in the first embodiment.

When only the dehumidification of the indoor air is performed without ventilating the indoor air (without introducing the outdoor air), as shown in FIG. 6, the bypass damper 71 and the outdoor outlet damper 65 are opened, and the outdoor inlet damper 62 is provided. The dehumidification damper 63 and the regeneration damper 64 operate to close the flow path. In addition, the first and second blowing fans 34 and 44 operate, the heater 53 is driven, and the dehumidification rotor 50 rotates gradually. In this case, the second blowing fan 44 rotates more slowly than the first blowing fan 34 so as to reduce the air discharged to the outside.

Most of the indoor air when the operation is made, the indoor inlet 11, the first exhaust passage 41, the bypass passage 70, the second air supply passage 32, the first blowing fan 34, the third air supply passage (33), through the dehumidification rotor 50 to the third air supply channel side, and the indoor discharge port 12 in order to be supplied back to the indoor space. In this process, since all the air passing through the third air supply passage 33 passes through the dehumidification rotor 50, dehumidification of indoor air is performed. In addition, the flow is different from the above-described first embodiment in that the indoor air flowing into the second air supply passage 32 does not pass through the heat exchanger 20.

In addition, a part of the indoor air introduced into the first exhaust passage 41 from the indoor inlet 11 is the second air passage 20b, the second exhaust passage 42, the second blowing fan 44, and the second air passage of the total heat exchanger. It is discharged to the outside through the three exhaust passage 43, the heater 53, the dehumidification rotor 50 toward the third exhaust passage 43, the outdoor discharge port 14 in order. At this time, the air discharged to the outside by the operation of the second blowing fan 44 is a small amount compared to the air circulating indoors because the second blowing fan 44 rotates at a low speed compared to the first blowing fan 43. In addition, since the air discharged to the outside passes through the dehumidification rotor 50 after being heated by the heater 53, the dehumidification rotor is regenerated.

8 to 10 show a third embodiment of the ventilation device according to the present invention. As shown in FIG. 8, the third embodiment includes an indoor inlet port 110 and an indoor outlet port 120 formed at an indoor side of the main body 100, and an outdoor inlet port formed at an outdoor side of the main body 100 ( 130 and an outdoor outlet 140.

An internal heat exchanger 200 is installed inside the main body 100 to exchange heat while passing through the first air passage 200a and the second air passage 200b where the air introduced from the outside and the air discharged from the indoor cross each other. do. In addition, the inside of the main body 100 to discharge the outdoor air introduced through the outdoor inlet 130 for the ventilation of the indoor space through the first air passage (200a) of the total heat exchanger (200) to the indoor outlet (120). An air supply passage and an exhaust passage for discharging the indoor air introduced through the indoor inlet 110 through the second air passage 200b of the total heat exchanger 200 to the outdoor outlet 140.

The air supply passage passes through the first air passage 310 and the first air passage 200a of the heat exchanger 200, which are formed so that the outdoor inlet 130 and the inlet of the first air passage 200a of the heat exchanger communicate with each other. It includes a second air supply flow path 320 made of a space for receiving, the second air supply flow path 320 and the third air supply flow path 330 formed to communicate the indoor discharge port (120). That is, the outdoor air passage passes through the first air supply passage 310, the first air passage 200a of the total heat exchanger, the second air passage 320, the third air passage 330, and the indoor outlet 120. Allow it to enter the indoor space. In addition, a first blowing fan 340 is installed in the second air supply passage 320 to blow air through the air supply passage.

The exhaust passage has a first exhaust passage 410 formed so that the indoor inlet 110 and the inlet of the second air passage 200b of the heat exchanger 200 communicate with each other, the outlet of the second air passage 200b of the heat exchanger and the outdoor It includes a second exhaust passage 420 for communicating the outlet 140. The exhaust flow path passes through the indoor air through the indoor inlet 110, the first exhaust passage 410, the second air passage 200b of the total heat exchanger, the second exhaust passage 420, and the outdoor exhaust 140. Allow exhaust. In addition, a second blowing fan 440 is installed inside the second exhaust passage 420 to blow air through the exhaust passage.

In addition, in the third embodiment, a part of the air of the second air supply passage 320 passing through the first air passage 200a of the total heat exchanger 200 flows toward the second exhaust passage 420. ) And a communication passage 430 for communicating the second exhaust passage 420.

In addition, the third air supply passage 330 and the communication passage 430 are divided by the partition plate 150 partitioning between the two passages, so that some sections are adjacent to each other, and the third air supply passage 330 and the communication passage The dehumidification rotor 500 for dehumidifying the air supplied to the indoor space is installed in the partition plate 150 partitioning between the 440. And a heater 530 for heating the air flowing toward the dehumidification rotor 500 is installed at the inlet side of the communication passage 430. Here, since the configuration and installation structure of the dehumidification rotor 500 are the same as in the first embodiment, a detailed description thereof will be omitted.

In addition, in the third embodiment, as shown in FIG. 9, air in the first exhaust passage 410 is directed toward the first air supply passage 310 in order to perform dehumidification through circulation of indoor air without introducing external air. Bypass passage 600 to allow the inflow, and the bypass damper 610 to selectively close one of the inlet of the bypass passage 600 and the inlet of the second air passage (200b) of the total heat exchanger (200) and And an outdoor inlet damper 620 for opening and closing the outdoor inlet 130.

In the third air supply passage 330, a partition plate 350 is provided to partition the inside of the third air supply passage 330 so as to guide air introduced into the third air supply passage 330 toward the dehumidification rotor 500. And a dehumidifying damper 630 for opening and closing the flow path in a space between the partition plate 160 on the side of the second air supply flow path 320. The air flowing into the third air supply passage 330 when the dehumidification damper 630 is opened bypasses the dehumidification rotor 500 and flows toward the indoor outlet 120, and when the dehumidification damper 630 is closed, the third air supply passage ( All the air introduced into the 330 is passed through the dehumidification rotor 500 to be dehumidified and then flow toward the indoor outlet 120.

In addition, in the communication passage 430, a partition plate 450 is provided for partitioning the air flowing into the communication passage 430 toward the dehumidification rotor 500, and the partition plate 450 and the second are provided. A regenerative damper 640 is provided to open and close the flow path between the partition plates 170 on the exhaust flow path 420. The air flowing into the communication passage 430 by the operation of the regeneration damper 640 flows toward the second exhaust passage 420 through the dehumidification rotor 500 (see FIG. 9), or as shown in FIG. 10. The outlet of the communication passage 430 is closed by the regeneration damper 640.

The outdoor outlet 140 can be opened and closed according to the user's needs so that the outdoor air can be prevented from flowing back into the main body 100 through the outdoor outlet 140 due to severe outdoor air or when the ventilation device is stopped. An outdoor outlet damper 650 is installed.

Operation of the ventilation apparatus according to the third embodiment is performed as follows.

As shown in FIG. 8, the bypass damper 610 closes the bypass flow path 600 and the outdoor inlet damper 620 and the outdoor outlet when performing indoor air ventilation and dehumidification of air introduced from the outside. Damper 650 is opened. In addition, the dehumidification damper 630 allows the air introduced into the third air supply passage 330 to pass through the dehumidification rotor 500, and the regeneration damper 640 has the air introduced into the communication passage 430 from the dehumidification rotor 500. It operates to flow to the second exhaust passage 420 through. That is, the regeneration damper 640 opens the communication passage 430 outlet. In addition, the first and second blowing fans 340 and 440 operate, the heater 530 is driven, and the dehumidification rotor 500 rotates gradually.

At this time, the outdoor air inlet 130, the first air supply passage 310, the first air passage (200a) of the heat exchanger, the second air supply passage 320, the first blowing fan 340, the third air supply passage ( 330), the dehumidification rotor 500 at the third air supply passage side, and the indoor discharge port 120 are sequentially introduced into the indoor space. Therefore, the air introduced from the outside is supplied to the room after dehumidification. And indoor air is the indoor inlet 110, the first exhaust passage 410, the second air passage (200b) of the heat exchanger, the second exhaust passage 420, the second blowing fan 440, the outdoor outlet 140 It is discharged to the outside through in turn. In addition, a part of the air flowing into the communication passage 430 from the second air supply passage 320 is heated by the heater 530 and passes through the dehumidification rotor 500, so that the dehumidification rotor 500 of the communication passage 430 side is Remove the moisture to regenerate the dehumidifying rotor 500. Air passing through the communication passage 430 flows to the second exhaust passage 420 and is discharged to the outside.

In the third embodiment, when performing dehumidification of indoor air without ventilating indoor air (without introduction of outside air), as shown in FIG. 9, the bypass damper 610 opens the bypass flow path 600 and simultaneously heat transfers. It operates to close the inlet of the second air passage 200b of the exchanger 200, and the outdoor inlet damper 620 is closed. In addition, the dehumidification damper 630 allows the air introduced into the third air supply passage 330 to pass through the dehumidification rotor 500, and the regeneration damper 640 has the air introduced into the communication passage 430 from the dehumidification rotor 500. It is operated to flow to the second exhaust passage 420 through. And the outdoor outlet damper 650 is opened. In addition, the first and second blowing fans 340 and 440 operate, the heater 530 is driven, and the dehumidification rotor 500 rotates gradually. In this case, the second blowing fan 440 rotates more slowly than the first blowing fan 340 so as to reduce the air discharged to the outside.

Most of the indoor air when the operation is made, the indoor inlet 110, the first exhaust passage 410, the bypass passage 600, the first air supply passage 310, the first air passage (200a), the first heat exchanger The second air supply flow path 320, the first blowing fan 340, the third air supply flow path 330, the third air supply flow path to the dehumidification rotor 500, the indoor exhaust port 120 in order to be supplied back to the interior space. In this process, all the air passing through the third air supply passage 330 passes through the dehumidification rotor 500, so that dehumidification of indoor air is performed.

Part of the air flowing into the communication passage 430 from the second air supply passage 320 is heated by the heater 530 and then passes through the dehumidification rotor 500, so that the dehumidification rotor 500 of the communication passage 430 side is dehydrated. Remove the moisture to regenerate the dehumidifying rotor 500. Air passing through the communication passage 430 flows to the second exhaust passage 420 and is discharged to the outside. At this time, the air discharged to the outside by the operation of the second blowing fan 440 is a small amount compared to the air circulating indoors because the second blowing fan 440 rotates at a low speed compared to the first blowing fan 340.

In addition, in the third embodiment, when only the ventilation is performed without the dehumidification operation, as shown in FIG. 10, the bypass flow path 600 is closed by the bypass damper 610, and the outdoor inlet damper 620 and the outdoor outlet damper 650. ) Opens. In addition, the dehumidification damper 630 is operated so that the air flowing into the third air supply passage 330 bypasses the dehumidification rotor 500, and the regeneration damper 640 closes the outlet of the communication passage 430. In addition, the first blower fan 340 and the second blower fan 440 operate, and the operation of the heater 530 and the dehumidification rotor 500 are stopped.

At this time, the outdoor air inlet 130, the first air supply passage 310, the first air passage (200a) of the heat exchanger, the second air supply passage 320, the first blowing fan 340, the third air supply passage ( 330), the indoor outlet 120 is sequentially introduced into the indoor space. At this time, the air flowing into the interior from the outside bypasses the dehumidification rotor 500 inside the third air supply passage 330 or only a part passes through the dehumidification rotor 500, and dehumidification because the dehumidification rotor 500 is not rotated. This is not done. And indoor air is the indoor inlet 110, the first exhaust passage 410, the second air passage (200b) of the heat exchanger, the second exhaust passage 420, the second blowing fan 440, the outdoor outlet 140 It is discharged to the outside through in turn. In this case, since the outlet of the communication passage 430 is closed by the regeneration damper 640, the flow toward the communication passage 430 does not occur.

11 and 12 show a fourth embodiment of the ventilation device according to the present invention. The fourth embodiment is a bypass passage 700 that can directly communicate the first exhaust passage 410 and the second air supply passage 320 in place of the bypass passage 600 and the bypass damper 610 in the third embodiment. And a bypass damper 710 for selectively closing any one of the bypass passage 700 and the heat exchanger 200, the second air passage 200b, the inlet side passage. There is a difference. The rest of the configuration is the same as in the third embodiment.

In the fourth embodiment, when dehumidification is performed together with ventilation, as shown in FIG. 12, the bypass flow path 700 is closed by the bypass damper 710, and the rest operates in the same manner as in the third embodiment. Therefore, the same as the ventilation and dehumidification operation in the third embodiment. In addition, although not shown in the drawings, even when only the ventilation is performed without the dehumidification operation, the substantial flow is made in the same manner as in the third embodiment.

When only the dehumidification of the indoor air is performed without ventilating the indoor air (without introducing the outdoor air), as shown in FIG. 11, the bypass damper 710 opens the bypass flow path 700 and at the same time the heat exchanger 200 The flow path of the second air passage 200b is closed, and the outdoor inlet damper 620 is closed. In addition, the dehumidification damper 630 allows the air introduced into the third air supply passage 330 to pass through the dehumidification rotor 500, and the regeneration damper 640 has the air introduced into the communication passage 430 from the dehumidification rotor 500. It is operated to flow to the second exhaust passage 420 through. And the outdoor outlet damper 650 is opened. In addition, the first and second blowing fans 340 and 440 operate, the heater 530 is driven, and the dehumidification rotor 500 rotates gradually. In this case, the second blowing fan 440 rotates more slowly than the first blowing fan 340 so as to reduce the air discharged to the outside.

Most of the indoor air when the operation is made, the indoor inlet 110, the first exhaust passage 410, the bypass passage 700, the second air supply passage 320, the first blowing fan 340, the third air supply passage 330, the third air supply path side dehumidification rotor 500, and then through the indoor outlet 120 is supplied to the indoor space again. In this process, all the air passing through the third air supply passage 330 passes through the dehumidification rotor 500, so that dehumidification of indoor air is performed. This flow is different from the above-described third embodiment in that the indoor air flowing into the second air supply passage 320 does not pass through the heat exchanger 200.

Part of the air flowing into the communication passage 430 from the second air supply passage 320 is heated by the heater 530 and then passes through the dehumidification rotor 500, so that the dehumidification rotor 500 of the communication passage 430 side is dehydrated. Remove the moisture to regenerate the dehumidifying rotor 500. Air passing through the communication passage 430 flows to the second exhaust passage 420 and is discharged to the outside.

As described in detail above, since the ventilation device according to the present invention performs dehumidification by the operation of the dehumidification rotor, there is an effect of performing a continuous dehumidification operation together with the ventilation and dehumidification of the room, and has a dehumidifying effect than the conventional It can increase.

In addition, since the present invention can circulate the indoor air through the bypass passage, there is an effect that can perform continuous dehumidification of the indoor air only through the circulation of the indoor air without introducing the outside air.

Claims (40)

A main body installed to connect the indoor and outdoor; A total heat exchanger installed inside the main body; An air supply passage installed in the main body and introducing outdoor air into the room via the heat exchanger; An exhaust passage installed in the main body and configured to discharge indoor air to the outside through the heat exchanger; In the ventilator comprising a dehumidification rotor having a dehumidifying unit and a regeneration unit, And the dehumidifying part is located in the air supply passage downstream of the heat exchanger, and the regeneration part is located in the exhaust flow path downstream of the heat exchanger. The method of claim 1, A dehumidifying damper for bypassing the dehumidifying part of the dehumidifying rotor to communicate with the room downstream of the air supply passage and a regeneration damper for bypassing the regeneration part of the dehumidifying rotor to communicate with the outdoors downstream of the exhaust flow path. Ventilation system. The method of claim 2, And when the ventilator is to operate in a ventilation mode, opening the dehumidification damper and the regeneration damper so that intake and exhaust are performed through the open dampers. The method of claim 2, When the ventilation device is to operate in a ventilation and dehumidification mode, the dehumidification damper is closed to allow the air supply passage to be sucked through the dehumidification part of the dehumidification rotor, and the regeneration damper is partially opened so that a part of the exhaust passage is part of the dehumidification rotor. Ventilation device characterized in that passing through the regeneration unit and a part is discharged to the outside through the regeneration damper. A main body installed to connect the indoor and outdoor; A total heat exchanger installed inside the main body; An air supply passage installed in the main body and introducing outdoor air into the room via the heat exchanger; An exhaust passage installed in the main body and configured to discharge indoor air to the outside through the heat exchanger; In the ventilator comprising a dehumidification rotor having a dehumidifying unit and a regeneration unit, The dehumidifying part is located in the air supply passage downstream of the heat exchanger, and the regeneration part is located in the exhaust flow path downstream of the heat exchanger; And a bypass passage on the upstream side of the exhaust passage to bypass the electrothermal exchanger and communicate with the air supply passage. The method of claim 5, The bypass passage comprises a damper for selectively opening and closing the bypass passage. The method of claim 6, And the bypass passage is formed so as to communicate with an upstream side of the exhaust passage and an upstream side of the air supply passage before passing through the total heat exchanger. The method of claim 7, wherein When the ventilator is to operate in the dehumidification mode, the damper of the bypass passage on the exhaust passage is opened, and some of the exhaust passage bypasses the heat exchanger, passes through the intake passage, passes through the dehumidification part of the heat exchanger and the dehumidification rotor, and is sucked into the room. And some of the exhaust passages are discharged outside the regeneration unit of the total heat exchanger and the dehumidification rotor. The method of claim 6, And the bypass passage is formed so as to communicate with an upstream side of the exhaust passage and the air supply passage after passing through the total heat exchanger. The method of claim 9, When the ventilator is to operate in the dehumidification mode, the damper of the bypass passage on the exhaust passage is opened so that some of the exhaust passage bypasses the heat exchanger, passes through the air supply passage, and passes through the dehumidification part of the dehumidification rotor to be sucked into the room. And some of the exhaust passages are discharged to the outside through the regeneration unit of the total heat exchanger and the dehumidification rotor. A main body installed to connect the indoor and outdoor; A total heat exchanger installed inside the main body; An air supply passage installed in the main body and introducing outdoor air into the room via the heat exchanger; An exhaust passage installed in the main body and configured to discharge indoor air to the outside through the heat exchanger; In the ventilator comprising a dehumidification rotor having a dehumidifying unit and a regeneration unit, A communication passage communicating the air supply passage downstream of the heat exchanger and the exhaust passage downstream of the electrothermal exchanger, The dehumidifying portion is located in the air supply passage downstream of the total heat exchanger, and the regeneration portion is located in the communication passage; Ventilation. The method of claim 11, A partition plate is installed between the communication passage and the air supply passage, The dehumidification rotor is installed on the partition plate, Ventilation. The method of claim 11, A dehumidification damper is installed at the downstream side of the air supply passage to allow the inflow of air to bypass the dehumidifying unit and communicate with the room; Further comprising a regeneration damper at a downstream side of the communication passage to open the outlet of the communication passage so that the inflow air communicates with the outside through the regeneration unit, or to close the outlet of the communication passage so that the inlet air flows into the room. Ventilation. The method of claim 13, When the ventilation device is to operate in the ventilation mode, the dehumidification damper is opened and the regenerative damper is closed, and the air supply passage bypasses the dehumidification part of the dehumidification rotor and is introduced into the room, and the indoor air is exhausted through the exhaust passage. Ventilation apparatus characterized in that the exhaust to. The method of claim 13, When the ventilation device is to operate in the ventilation and dehumidification mode, the dehumidification damper is closed, the regeneration damper is opened, and a part of the air supply passage is sucked through the dehumidification part of the dehumidification rotor, and a part of the air supply passage Ventilator characterized in that the discharge through the regeneration unit of the dehumidification rotor to the outside. A main body installed to connect the indoor and outdoor; A total heat exchanger installed inside the main body; An air supply passage installed in the main body and introducing outdoor air into the room via the heat exchanger; An exhaust passage installed in the main body and configured to discharge indoor air to the outside through the heat exchanger; In the ventilator comprising a dehumidification rotor having a dehumidifying unit and a regeneration unit, A communication passage communicating the air supply passage downstream of the heat exchanger and the exhaust passage downstream of the electrothermal exchanger, The dehumidifying portion is located in the air supply passage downstream of the total heat exchanger, and the regeneration portion is located in the communication passage, An upstream side of the exhaust flow passage provided with a bypass flow passage bypassing the heat exchanger and communicating with the air supply flow passage, Ventilation. The method of claim 16, The bypass passage comprises a damper for selectively opening and closing the bypass passage. The method of claim 17, And the bypass passage is formed so as to communicate with an upstream side of the exhaust passage and an upstream side of the air supply passage before passing through the total heat exchanger. The method of claim 18, When the ventilation device is to operate in the dehumidification mode, the damper of the bypass passage on the exhaust passage is opened so that all of the exhaust passage bypasses the heat exchanger and passes through the air supply passage and the heat exchanger, and some of the exhaust passages of the dehumidification rotor Ventilation device through the dehumidification unit to be sucked into the room, and part of the exhaust passage is discharged to the outside through the regeneration unit of the dehumidification rotor. The method of claim 17, And the bypass passage is formed so as to communicate with an upstream side of the exhaust passage and the air supply passage after passing through the total heat exchanger. The method of claim 20, When the ventilation device is to operate in the dehumidification mode, the damper of the bypass passage on the exhaust passage is opened so that all of the exhaust passage bypasses the heat exchanger and passes through the air supply passage, and part of the exhaust passage dehumidifies the dehumidification rotor. And a part of the exhaust passage is discharged to the outside through the regeneration unit of the dehumidification rotor. delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete

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