KR102381927B1 - Ventilator - Google Patents

Abstract

The present invention is a ventilation device capable of preventing contamination of an indoor space caused when harmful substances remaining inside the ventilation device are introduced into the room by discharging harmful substances remaining inside the ventilation device to the outside during operation of the ventilation device Its purpose is to provide
The present invention for realizing this is a first exhaust chamber into which indoor air is introduced, a second exhaust chamber in which indoor air passing through the first exhaust chamber is discharged to the outdoors, a first air supply chamber into which outdoor air is introduced, and the first air supply chamber. A second air supply chamber for supplying outdoor air passing through the first air chamber into the room, and heat exchange between the indoor air flowing from the first exhaust chamber to the second exhaust chamber and the outdoor air flowing from the first air supply chamber to the second air supply chamber In the ventilation device including the total heat exchanger, the ventilation device includes at least one operation mode for controlling the condition of indoor air, and when the ventilation device is operated, the ventilation system inside the ventilation device precedes the operation mode. It is characterized in that it is configured to perform a purge mode for discharging air to the outside until a set condition is satisfied.

Description

Ventilation device {VENTILATOR}

The present invention relates to a ventilation apparatus, and more particularly, to a ventilation apparatus having a purge function for discharging harmful substances remaining in the ventilation apparatus to the outside prior to the operation mode of the ventilation apparatus when the ventilation apparatus is operated.

In general homes and offices, cooling and heating devices are installed to perform indoor cooling and heating according to seasonal changes. , boilers, etc.

Indoors, such as general homes and offices, where such cooling and heating devices are installed, are kept sealed to improve cooling and heating efficiency. A bad odor is generated or foreign substances such as dust become floating. Therefore, the indoor air is ventilated at regular intervals to remove such odors or dust from the room. Ventilation is performed to more quickly exhaust the polluted indoor air to the outdoors while maintaining the indoor temperature, and to supply fresh outdoor air to the room. device is used.

The conventional ventilation device has operation mode functions such as a total heat exchange mode, a bypass mode for outdoor air cooling, and an air cleaning mode.

However, when the ventilation device is not in operation, contaminants such as dust are accumulated inside the ventilation device. In particular, toxic substances such as volatile organic compounds (VOCs) are released into the ventilation system for a certain period of time after the production of the ventilation system. Since the residual harmful substances are introduced into the room, there is a problem that the indoor space is contaminated by the harmful substances and adversely affects the health of the occupants.

Prior art related to the ventilation device is disclosed in Patent Registration No. 10-1279997, Patent Registration No. 10-1560192, and the like.

The present invention has been devised to solve the above-mentioned problems, and when the ventilation device is operated, harmful substances remaining inside the ventilation device are discharged to the outside, and the harmful substances remaining inside the ventilation device are introduced into the room. Its purpose is to provide a ventilation system that can prevent pollution of indoor space.

A ventilation device according to an embodiment of the present invention for realizing the object as described above includes a first exhaust room into which indoor air is introduced, and a second exhaust room through which indoor air passing through the first exhaust room is discharged to the outside. , a first air supply chamber into which outdoor air flows, a second air supply chamber for supplying outdoor air passing through the first air supply chamber into the room, and indoor air and the first air flowing from the first exhaust chamber to the second exhaust chamber. A ventilation device comprising a total heat exchanger for exchanging heat between outdoor air flowing from an air supply chamber to a second air supply chamber, wherein the ventilation apparatus includes at least one operation mode for controlling a condition of indoor air, During operation, a purge mode of discharging the air inside the ventilation device to the outside prior to the operation mode is performed until a set condition is satisfied, wherein the purge mode includes indoor air introduced through the second air supply chamber and the It is characterized in that the air inside the ventilation device is discharged to the outside by using the indoor air introduced through the first exhaust chamber.

A ventilation device according to another embodiment of the present invention includes a first exhaust chamber through which indoor air is introduced, a second exhaust chamber through which indoor air passing through the first exhaust chamber is discharged to the outdoors, and a first class through which outdoor air is introduced. Air chamber, a second air supply chamber that supplies outdoor air passing through the first air supply chamber into the room, and indoor air flowing from the first exhaust chamber to the second exhaust chamber and flowing from the first air supply chamber to the second air supply chamber A ventilation apparatus comprising a total heat exchanger for exchanging heat between outdoor air, wherein the ventilation apparatus includes at least one operation mode for controlling a condition of indoor air, and when the ventilation apparatus is operated, the operation mode precedes the operation mode. The purge mode for discharging the air inside the ventilation device to the outside is performed until the set conditions are satisfied, but at one side of the first exhaust room, the second exhaust room, the first air room, the second air room and the total heat exchanger A bypass passage is formed with a diaphragm interposed therebetween, and in the purge mode, indoor air introduced through the second air supply chamber passes through the total heat exchanger, the first air supply chamber, the bypass passage and the second exhaust chamber sequentially. It is characterized in that the air inside the ventilation device is discharged to the outside by being discharged to the outside via the furnace.

The setting condition may be set when a set time elapses or when the air quality concentration value sensed in the supply side indoor air flow path or inside the ventilation device satisfies a set target air quality concentration value range.

A second damper may further include a second damper for opening and closing a flow path of air exhausted from the second exhaust chamber to the outdoors, wherein, in the purge mode, the second damper is opened.

Further comprising a third damper for opening and closing the flow path of the air introduced into the first air supply chamber, in the purge mode, the third damper may be configured to be closed.

Further comprising: a first damper for opening and closing a flow path of air introduced into the first exhaust chamber; and a fourth damper for opening and closing a flow path of air supplied from the second air supply chamber to the room; At least one of the first damper and the fourth damper may be opened.

In the purge mode, some of the indoor air introduced through the second air supply chamber is branched into the bypass passage and discharged to the outdoors through the bypass passage and the second exhaust chamber sequentially. .

A ventilation device according to another embodiment of the present invention includes a first exhaust chamber into which indoor air is introduced, a second exhaust chamber in which indoor air passing through the first exhaust chamber is discharged to the outdoors, and a first exhaust chamber into which outdoor air is introduced. A supply air chamber, a second air supply chamber for supplying outdoor air passing through the first air supply chamber into the room, and the indoor air flowing from the first exhaust chamber to the second exhaust chamber and flows from the first air supply chamber to the second air supply chamber A ventilation device comprising a total heat exchanger for exchanging heat between outdoor air, wherein the ventilation device includes at least one operation mode for controlling a condition of indoor air, and prior to the operation mode when the ventilation device is operated A purge mode for discharging the air inside the ventilator to the outside is performed until a set condition is satisfied, and a first damper for opening and closing the flow path of the air introduced into the first exhaust chamber, and from the second exhaust chamber A second damper for opening and closing the flow path of air exhausted to the outside, a backwind prevention damper for opening and closing the flow path of the air introduced into the first air supply chamber, and opening and closing the flow path of air supplied from the second air supply chamber into the room In the purge mode, the second damper and the headwind prevention damper may be opened, and at least one of the first damper and the fourth damper may be opened.

and an exhaust blower for forcibly exhausting air from the second exhaust chamber to the outside, and in the purge mode, the exhaust blower may be operated.

A bypass passage is formed on one side of the first exhaust chamber, the second exhaust chamber, the first air supply chamber, the second air chamber, and the total heat exchanger with a diaphragm therebetween, and the diaphragm includes the first exhaust chamber and the bypass A first communication port connecting the passage, a second communication port connecting the second exhaust chamber and the bypass passage, and a third communication port connecting the first air supply chamber and the bypass passage are formed, the first communication a fifth damper for opening and closing the sphere and a sixth damper for opening and closing the third communication port, wherein in the purge mode, the fifth damper is selectively opened and closed, and the sixth damper is opened can be

and an eighth damper for opening and closing an air flow path connecting the second air supply chamber and the second exhaust chamber, and in the purge mode, the eighth damper is opened.

A fourth communication port for connecting the second air supply chamber and the bypass passage is formed in the partition plate, and a seventh damper for opening and closing the fourth communication port is provided, and in the purge mode, the seventh damper is It can be configured to be open.

and an eighth damper for opening and closing an air flow path connecting the second air supply chamber and the second exhaust chamber, and in the purge mode, the eighth damper is opened.

A plasma ion generator for sterilizing the supplied air may be provided in the air supply passage connected to the second air supply chamber or the second air supply chamber.

The purge mode may be performed when the ventilation device is initially installed.

According to the ventilation device according to the present invention, when the ventilation device is operated, a purge mode for discharging harmful substances remaining in the ventilation device to the outside is performed before the operation mode of the ventilation device is performed until a preset condition is satisfied, so that the inside of the ventilation device is operated. It is possible to prevent contamination of the indoor space caused when harmful substances remaining in the room are introduced into the room.

In addition, by performing the purge mode of the ventilation device using the air supply-side indoor air flowing in through the second air supply chamber, harmful substances remaining in the supply-side indoor air flow path connected to the second air supply chamber can be effectively discharged to the outdoors. .

In addition, a plurality of communication ports are formed in the diaphragm, and in the purge mode, a damper provided in the communication port is opened, and an exhaust blower is operated to form a flow path for purged air. It is possible to effectively purge the entire space and the lower space.

1 is a schematic plan view of a ventilation device according to a first embodiment of the present invention;
2 is a side schematic view of a ventilation device according to a first embodiment of the present invention;
3 is a schematic plan view showing a total heat exchange mode of the ventilation device according to the first embodiment of the present invention;
Fig. 4 is a schematic side view of Fig. 3;
5 is a schematic plan view showing a bypass mode for outdoor air cooling of the ventilation device according to the first embodiment of the present invention;
Fig. 6 is a schematic side view of Fig. 5;
7 is a schematic plan view showing a purge mode of the ventilation device according to the first embodiment of the present invention;
Fig. 8 is a schematic side view of Fig. 7;
9 is a schematic plan view showing a purge mode of the ventilation device according to the second embodiment of the present invention;
10 is a schematic plan view showing a purge mode of the ventilation device according to the third embodiment of the present invention;
11 is a schematic plan view showing a purge mode of the ventilation device according to the fourth embodiment of the present invention;
12 is a schematic plan view showing a purge mode of the ventilation device according to the fifth embodiment of the present invention.

Hereinafter, the configuration and operation of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, in the ventilation device 1 according to the first embodiment of the present invention, a first exhaust chamber 10 through which indoor air is introduced, and an indoor space through the first exhaust chamber 10 are provided. A second exhaust chamber 20 for discharging air to the outdoors, a first air supply chamber 30 into which outdoor air flows, and a second air supply chamber for supplying outdoor air passing through the first air supply chamber 30 to the interior ( 40), and heat exchange between the indoor air flowing from the first exhaust chamber 10 to the second exhaust chamber 20 and the outdoor air flowing from the first air supply chamber 30 to the second air supply chamber 40 It includes a total heat exchanger (50) made. In addition, the ventilation device 1 has the first exhaust chamber 10 , the second exhaust chamber 20 , and the first air supply chamber 30 in the space above the diaphragm 60 with respect to the diaphragm 60 . , a second air supply chamber 40 and a total heat exchanger 50 are provided, and a bypass passage 70 is provided in the space below the diaphragm 60 .

In addition, the ventilation device (1) of the present invention has a total heat exchange mode in which heat exchange is performed between exhausted indoor air and supplied outdoor air, and a bypass for cooling the indoor air by supplying outdoor air to the indoor side without heat exchange with indoor air. The air remaining in the ventilation device 1 and dust or volatile organic compounds contained therein until the set conditions are satisfied prior to performing the operation mode during initial operation of the operation mode such as pass mode and the ventilation device 1 . It includes a purge mode function to discharge harmful substances such as (VOC) to the outdoors.

In one embodiment, the 'set condition' may be set to 'when a set time elapses'. In this case, the 'set time' considers the volume of the internal space of the ventilation device 1 and the length of a connection duct (not shown) that is connected to the ventilation device 1 and flows through the ventilation device 1 . ) of the internal space and the total flow rate of air remaining in the connecting duct can be set to a time that can be discharged to the outdoors.

In another embodiment, the 'set condition' is an air quality concentration value of dust, CO2, VOC, etc. detected by an air quality sensor (not shown) installed in the air supply side indoor air flow path or the air flow path inside the ventilation device 1 may be set to 'when the set target air quality concentration numerical range is satisfied.

On the other hand, the ventilation apparatus 1 of the present invention includes a mode setting unit (not shown) for selecting any one of the purge mode and the operation mode, and the ventilation apparatus 1 according to the mode set in the mode setting unit. ) includes a control unit (not shown) for controlling the operation.

The purge mode is performed for a set time when the ventilation device 1 is initially installed at the installation site. In addition, the purge mode is performed before performing the operation mode whenever the ventilator 1 is initially operated.

An indoor air inlet 11 through which indoor air is introduced is provided on the indoor side of the first exhaust chamber 10 , and the indoor air inlet 11 opens and closes a flow path for air introduced into the first exhaust chamber 10 . A first damper 12 for A first communication port 10a connecting the first exhaust chamber 10 and the bypass passage 70 is formed in the diaphragm 60 located in the first exhaust chamber 10, and the first communication hole ( A fifth damper 13 for opening and closing 10a) is provided.

An indoor air outlet 21 through which indoor air is discharged to the outdoors is provided on the outdoor side of the second exhaust chamber 20, and the indoor air outlet 21 is provided with air exhausted from the second exhaust chamber 20 to the outdoors. A second damper 22 for opening and closing the flow path is provided. A second communication port 20a connecting the second exhaust chamber 20 and the bypass passage 70 is formed in the diaphragm 60 located in the second exhaust chamber 20, and the second communication port ( 20a) is not provided with a separate damper and is always maintained in an open state. In addition, an exhaust blower 23 for forcibly exhausting air to the outside is provided in the second exhaust chamber 20 .

An outdoor air inlet 31 through which outdoor air is introduced is provided on the outdoor side of the first air supply chamber 30, and the outdoor air inlet 31 opens and closes a flow path for air introduced into the first air supply chamber 30. A third damper 32 for A third communication port 30a connecting the first air supply chamber 30 and the bypass passage 70 is formed in the diaphragm 60 located in the first air supply chamber 30, and the third communication port ( A sixth damper 33 for opening and closing 30a) is provided.

An outdoor air outlet 41 through which outdoor air is supplied to the indoor side is provided on the indoor side of the second air supply chamber 40, and the outdoor air outlet 41 has air supplied from the second air supply chamber 40 into the room. A fourth damper 42 for opening and closing the flow path is provided. In addition, the second air supply chamber 40 is provided with an air supply blower 43 for forcibly supplying air into the room. In addition, a plasma ion generator 44 for sterilizing the supplied air is provided in the air supply passage connecting the second air supply chamber 40 and the outdoor air outlet 41 or the second air supply chamber 44 . The plasma ion generator 44 functions to provide more clean air supplied by sterilizing bacteria and the like in the air supply passage that may remain even after the purge mode is performed.

In the fifth damper 13 and the sixth damper 33 shown in FIG. 2 , a solid line indicates a closed state, and a dotted line indicates an open state.

The total heat exchanger 50 has a structure in which a flow path through which indoor air flows and a flow path through which outdoor air flows are alternately formed so that heat exchange between indoor air and outdoor air is possible. A filter 51 for filtering foreign substances contained in the air may be provided on one side of the total heat exchanger 50 facing the first air supply chamber 30 .

As described above, the ventilation device 1 has various operation mode functions. Hereinafter, with reference to FIGS. 3 to 6 , among the operation modes in the ventilation device 1 according to the first embodiment of the present invention, The total heat exchange mode and the bypass mode will be described as examples.

In the drawing, an arrow indicates the flow path of indoor air and outdoor air, a solid arrow indicates a flow path in the space above the diaphragm 60 , and a dotted arrow indicates a bypass passage 70 located below the diaphragm 60 . It shows the flow path in

First, referring to FIGS. 3 and 4 , in the total heat exchange mode, the first damper 12 , the second damper 22 , the third damper 32 and the fourth damper 42 are opened, and the fifth damper (13) and the sixth damper (33) are closed. The blower 23 for exhaust and the blower 43 for supply air are operated.

Therefore, in the total heat exchange mode, indoor air flows into the first exhaust chamber 10 through the indoor air inlet 11 and then passes through the total heat exchanger 50 and the second exhaust chamber 20 to the indoor air outlet 21 ) through the exhaust to the outside. At the same time, outdoor air flows into the first air supply chamber 30 through the outdoor air inlet 31, and then passes through the total heat exchanger 50 and the second air chamber 40 to the indoor through the outdoor air outlet 41. is supplied The indoor air and the outdoor air exchange heat while passing through the total heat exchanger (50).

5 and 6, in the bypass mode, the first damper 12, the second damper 22, the third damper 32, the fourth damper 42, and the fifth damper 13 are open. and the sixth damper 33 is closed. The blower 23 for exhaust and the blower 43 for supply air are operated.

Therefore, in the bypass mode, the indoor air flows into the first exhaust chamber 10 through the indoor air inlet 11, and then passes through the first communication port 10a, and the flow path is switched downward to the bypass passage ( 70), the flow passage is switched upward through the second communication port 20a, flows into the second exhaust chamber 20, and then is discharged to the outside through the indoor air outlet 21.

At the same time, after the outdoor air flows into the first air supply chamber 30 through the outdoor air inlet 31 , it passes through the filter 51 and the total heat exchanger 50 and flows into the second air supply chamber 40 . Air is supplied into the room through the outdoor air outlet (41).

As described above, in the bypass mode, since indoor air passes through the bypass passage 70 without passing through the total heat exchanger 50, heat exchange is not performed between the exhausted indoor air and the supplied outdoor air, and the outdoor air has a temperature Air is supplied to the indoor side without change.

Hereinafter, a purge mode of the ventilation device according to the first embodiment of the present invention will be described with reference to FIGS. 7 and 8 . The purge mode is operated until the set conditions as described above are satisfied prior to the above-described operation mode when the ventilation device 1 is operated to remove the air remaining inside the ventilation device 1 and harmful substances contained therein to the outside. operated to eject.

In one embodiment, in the purge mode, the first damper 12 , the second damper 22 , the fourth damper 42 , the fifth damper 13 , and the sixth damper 33 are opened, and the third damper The damper 32 is closed. In addition, the blower 23 for exhaust is operated, and the blower 43 for supply air is not operated.

Accordingly, in the purge mode, the indoor air introduced into the second air supply chamber 40 through the outdoor air outlet 41 according to the operation of the air supply blower 43 passes through the total heat exchanger 50 to the first air supply chamber. (30), the flow passage is converted downward through the third communication port (30a) formed in the first air supply chamber (30), and after passing through the bypass passage (70), the second communication hole (20a) The flow passage is converted upward through the ventilator and flows into the second exhaust chamber 20 , and then is discharged to the outside through the indoor air outlet 21 .

At the same time, the indoor air is introduced into the first exhaust chamber 10 through the indoor air inlet 11 . Part of the indoor air introduced into the first exhaust chamber 10 passes through the total heat exchanger 50 and flows into the second exhaust chamber 20 , and then is discharged to the outside through the indoor air outlet 21 . The remainder of the indoor air introduced into the first exhaust chamber 10 passes through the first communication port 10a, the flow path is switched downward, passes through the bypass passage 70, and then passes through the second communication hole 20a. After passing through, the flow path is switched upward and introduced into the second exhaust chamber 20 , and then discharged to the outside through the indoor air outlet 21 .

In another embodiment, in the purge mode, at least one of the first damper 12 and the fourth damper 42 may be opened. That is, the first damper 12 may be opened and the fourth damper 42 may be closed, or the first damper 12 may be closed and the fourth damper 42 may be opened. In this case, the purge mode is performed using either one of the supply-side indoor air and the ventilation-side indoor air.

Meanwhile, in the purge mode as described above, when the first damper 12, the fourth damper 42, the fifth damper 13, and the sixth damper 33 are all open, the second air supply chamber 40 Since the total flow rate of the indoor air on the supply side flowing in through the total heat exchanger (50) passes through the total heat exchanger (50), a large static pressure is applied. Since it passes through (50) and the remaining flow passes through the bypass passage (70), a relatively small static pressure is applied compared to the indoor air on the supply side.

Due to this difference in static pressure, when the exhaust blower 23 is operated, the flow rate at which the indoor air on the supply side is sucked may be less than the flow rate at which the indoor air on the ventilation side is sucked. In this case, the flow rate at which the indoor air on the supply side is sucked It may not be possible to secure enough airflow, so there may be a problem that the dust and harmful substances remaining in the indoor air flow path on the supply side cannot be effectively removed.

As another embodiment to solve this problem, in the purge mode, the fifth damper 13 may be selectively opened and closed, and the sixth damper 33 may be opened. That is, in the purge mode, the fifth damper 13 is closed to block the indoor air flowing into the first exhaust chamber 10 from flowing into the bypass passage 70 through the first communication port 10a, or By configuring the fifth damper 13 to be closed after being opened only for a certain period of time, the flow rate of the indoor air introduced through the air supply-side indoor air flow path can be sufficiently secured.

As described above, in the purge mode, at least one of the first damper 12 and the fourth damper 42 is opened, the fifth damper 13 is selectively opened and closed, and the sixth damper 33 is opened The configuration can be equally applied to the embodiments to be described below.

If the purge mode is performed prior to performing the operation mode of the ventilation device 1 as described above, the purge mode for discharging harmful substances remaining inside the ventilation device 1 to the outside when the ventilation device 1 is operated is performed. By performing the operation until the set conditions are satisfied prior to the operation mode of the ventilation device 1, the indoor space can be saved by preventing contamination of the indoor space caused when harmful substances remaining inside the ventilation device 1 are introduced into the room. It can be kept clean.

In addition, by performing the purge mode of the ventilation device 1 using the air supply-side indoor air flowing in through the second air supply chamber 40 , harmful substances remaining in the air supply-side indoor air flow path connected to the second air supply chamber 40 are performed. The material can be effectively discharged outdoors. Therefore, when the operation mode of the ventilation device 1 is activated after the purge mode is completed, the harmful substances are removed in the air supply-side connection duct connected to the second air supply chamber 40, so clean air is passed through the supply-side connection duct. can be supplied indoors.

Hereinafter, the configuration and operation of modified embodiments of the ventilation device 1 according to the present invention will be described with reference to FIGS. 9 to 12 .

9, the ventilation device 1 according to the second embodiment of the present invention includes all of the configurations of the first embodiment described above, and the diaphragm 60 has a second air supply chamber 40 and a bypass passage. A fourth communication port 40a connecting the 70 is formed, and a seventh damper 45 for opening and closing the fourth communication port 40a is further included, and in the purge mode, the seventh damper 45 ) consists of open ones.

In the purge mode according to the present embodiment, the first damper 12, the second damper 22, the fourth damper 42, the fifth damper 13, the sixth damper 33, and the seventh damper 45 is open, and the third damper 32 is closed. In addition, the blower 23 for exhaust is operated, and the blower 43 for supply air is not operated.

Accordingly, in the purge mode, the indoor air flows into the second air supply chamber 40 through the outdoor air outlet 41 according to the operation of the air supply blower 43 . Part of the indoor air introduced into the second air supply chamber 40 passes through the total heat exchanger 50 and flows into the first air supply chamber 30, and a third communication port formed in the first air supply chamber 30 ( After passing through 30a), the flow path is switched downward, and after passing through the bypass passage 70, the flow path is switched upward through the second communication hole 20a and flows into the second exhaust chamber 20, and then the indoor air It is discharged to the outside through the outlet (21). The remainder of the indoor air introduced into the second air supply chamber 40 passes through the fourth communication port 40a, the flow path is switched downward, passes through the bypass passage 70, and then passes through the second communication hole 20a. After passing through, the flow path is switched upward and introduced into the second exhaust chamber 20 , and then discharged to the outside through the indoor air outlet 21 .

At the same time, the indoor air is introduced into the first exhaust chamber 10 through the indoor air inlet 11 . Part of the indoor air introduced into the first exhaust chamber 10 passes through the total heat exchanger 50 and flows into the second exhaust chamber 20 , and then is discharged to the outside through the indoor air outlet 21 . The remainder of the indoor air introduced into the first exhaust chamber 10 passes through the first communication port 10a, the flow path is switched downward, passes through the bypass passage 70, and then passes through the second communication hole 20a. After passing through, the flow path is switched upward and introduced into the second exhaust chamber 20 , and then discharged to the outside through the indoor air outlet 21 .

According to the configuration of the second embodiment as described above, compared to the first embodiment, the fourth communication port 40a and the seventh damper 45 are additionally configured to allow room air to pass through the bypass passage 70 more widely. Since it passes over the area, harmful substances remaining in the bypass passage 70 can be more effectively discharged.

Referring to FIG. 10 , the ventilation device 1 according to the third embodiment of the present invention includes all of the configurations of the first embodiment described above, and includes the second air supply chamber 40 and the second exhaust chamber 20 . An eighth damper 80 for opening and closing a connecting air flow path is included, and the eighth damper 80 is opened in the purge mode.

In the purge mode according to the present embodiment, the first damper 12, the second damper 22, the fourth damper 42, the fifth damper 13, the sixth damper 33, and the eighth damper 44 is open, and the third damper 32 is closed. In addition, the blower 23 for exhaust is operated, and the blower 43 for supply air is not operated.

Accordingly, in the purge mode, the indoor air flows into the second air supply chamber 40 through the outdoor air outlet 41 according to the operation of the air supply blower 43 . Part of the indoor air introduced into the second air supply chamber 40 passes through the total heat exchanger 50 and flows into the first air supply chamber 30, and a third communication port formed in the first air supply chamber 30 ( After passing through 30a), the flow path is switched downward, and after passing through the bypass passage 70, the flow path is switched upward through the second communication hole 20a and flows into the second exhaust chamber 20, and then the indoor air It is discharged to the outside through the outlet (21). The remainder of the indoor air introduced into the second air supply chamber 40 passes through the open space of the eighth damper 80 and flows into the second exhaust chamber 20, and then passes through the indoor air outlet 21 to the outdoor air. is emitted as

At the same time, the indoor air is introduced into the first exhaust chamber 10 through the indoor air inlet 11 . Part of the indoor air introduced into the first exhaust chamber 10 passes through the total heat exchanger 50 and flows into the second exhaust chamber 20 , and then is discharged to the outside through the indoor air outlet 21 . The remainder of the indoor air introduced into the first exhaust chamber 10 passes through the first communication port 10a, the flow path is switched downward, passes through the bypass passage 70, and then passes through the second communication hole 20a. After passing through, the flow path is switched upward and introduced into the second exhaust chamber 20 , and then discharged to the outside through the indoor air outlet 21 .

According to the configuration of the third embodiment as described above, compared with the first embodiment, an eighth damper 80 for opening and closing the air passage connecting the second air supply chamber 40 and the second exhaust chamber 20 is added. Since the indoor air additionally passes through the flow path connecting the second air supply chamber 40 and the second exhaust chamber 20 by including the It can be effectively discharged through the open space of the air chamber 40 and the eighth damper 80 and the second exhaust chamber 20 .

11, the ventilation device 1 according to the fourth embodiment of the present invention includes all of the configurations of the first embodiment described above, and includes a fourth communication port 40a added in the second embodiment and The seventh damper 45 and the eighth damper 80 added in the third embodiment are included together, and in the purge mode, the seventh damper 45 and the eighth damper 80 are is open

In the purge mode according to the present embodiment, the first damper 12, the second damper 22, the fourth damper 42, the fifth damper 13, the sixth damper 33, the seventh damper 45 and the eighth damper 80 is open, and the third damper 32 is closed. In addition, the blower 23 for exhaust is operated, and the blower 43 for supply air is not operated.

Accordingly, in the purge mode, the indoor air flows into the second air supply chamber 40 through the outdoor air outlet 41 according to the operation of the air supply blower 43 . Part of the indoor air introduced into the second air supply chamber 40 passes through the total heat exchanger 50 and flows into the first air supply chamber 30, and a third communication port formed in the first air supply chamber 30 ( After passing through 30a), the flow path is switched downward, and after passing through the bypass passage 70, the flow path is switched upward through the second communication hole 20a and flows into the second exhaust chamber 20, and then the indoor air It is discharged to the outside through the outlet (21). The remaining part of the indoor air introduced into the second air supply chamber 40 passes through the fourth communication port 40a, the flow path is switched downward, and passes through the bypass passage 70, followed by the second communication hole 20a. The flow passage is converted upward through the ventilator and flows into the second exhaust chamber 20 , and then is discharged to the outside through the indoor air outlet 21 . In addition, another part of the indoor air introduced into the second air supply chamber 40 passes through the open space of the eighth damper 80 and flows into the second exhaust chamber 20, after which the indoor air outlet ( 21) to the outside.

At the same time, the indoor air is introduced into the first exhaust chamber 10 through the indoor air inlet 11 . Part of the indoor air introduced into the first exhaust chamber 10 passes through the total heat exchanger 50 and flows into the second exhaust chamber 20 , and then is discharged to the outside through the indoor air outlet 21 . The remainder of the indoor air introduced into the first exhaust chamber 10 passes through the first communication port 10a, the flow path is switched downward, passes through the bypass passage 70, and then passes through the second communication hole 20a. After passing through, the flow path is switched upward and introduced into the second exhaust chamber 20 , and then discharged to the outside through the indoor air outlet 21 .

According to the configuration of the fourth embodiment as described above, compared to the first to third embodiments, since indoor air passes over a wider area of the bypass passage 70 , harmful substances remaining in the bypass passage 70 are removed. Since it can be discharged more effectively and additionally passes through the flow path connecting the second air supply chamber 40 and the second exhaust chamber 20, harmful substances remaining in the flow path connected to the air supply side are removed from the second air supply chamber 40 ) and the open space of the eighth damper 80 and the second exhaust chamber 20 can be effectively discharged.

12, the ventilation device 1 according to the fifth embodiment of the present invention is different in that the third damper 32 is replaced with a headwind prevention damper 34 in the configuration of the first embodiment described above. , and other configurations may be applied in the same manner as in the configuration of the first embodiment.

In the purge mode according to the present embodiment, the first damper 12 , the second damper 22 , the fourth damper 42 , the fifth damper 13 , the sixth damper 33 , and the headwind prevention damper 34 . is open, and the third damper 32 is closed. In addition, the blower 23 for exhaust is operated, and the blower 43 for supply air is not operated.

In the purge mode, the indoor air introduced into the second air supply chamber 40 through the outdoor air outlet 41 according to the operation of the air supply blower 43 passes through the total heat exchanger 50 to the first air supply chamber 30 ), passes through the third communication port 30a formed in the first air supply chamber 30, the flow path is switched downward, passes through the bypass passage 70, and then passes through the second communication hole 20a Thus, the flow path is switched upward and introduced into the second exhaust chamber 20 , and then discharged to the outside through the indoor air outlet 21 .

According to the flow of indoor air as described above, the headwind prevention damper 34 is formed by the pressure difference between the pressure inside the first air supply chamber 30 located on one side and the outdoor pressure located on the other side with respect to the headwind prevention damper 34 as a reference. It can be opened as shown in FIG. 12 . In this case, after the outdoor air flows into the first air supply chamber 30 through the open space of the headwind prevention damper 34, the third communication port 30a, the bypass passage 70, and the second communication port 20a ) and the second exhaust chamber 20 and the indoor air outlet 21 are discharged to the outside.

Therefore, according to the configuration of the present embodiment, the purge mode can be performed by additionally using not only indoor air but also outdoor air in the purge mode, so that harmful substances remaining inside the ventilation device 1 can be discharged more quickly and effectively. there is.

As another embodiment, in the configuration of the second to fourth embodiments described above, the third damper 32 may be replaced with the headwind prevention damper 34 .

As described above, the present invention is not limited to the above-described embodiments, and obvious modifications can be made by those of ordinary skill in the art to which the present invention pertains without departing from the technical spirit of the present invention as claimed in the claims. It is possible, and such modifications fall within the scope of the present invention.

1: ventilation device 10: first exhaust room
10a: first communication port 11: indoor air inlet
12: first damper 13: fifth damper
20: second exhaust room 20a: second communication port
21: indoor air outlet 22: second damper
23: exhaust fan 30: first air room
30a: 3rd communication port 31: outdoor air inlet
32: third damper 33: sixth damper
34: Backwind prevention damper 40: Second air room
40a: 4th communication port 41: outdoor air outlet
42: fourth damper 43: blower for air supply
44: plasma ion generator 45: 7th damper
50: total heat exchanger 51: filter
60: diaphragm 70: bypass passage
80: eighth damper

Claims (15)

A first exhaust chamber into which indoor air is introduced, a second exhaust chamber for discharging indoor air passing through the first exhaust chamber to the outdoors, a first air supply chamber into which outdoor air flows, and outdoor air passing through the first air supply chamber. Ventilation comprising a second air supply room for supplying air into the room, and a total heat exchanger in which heat exchange is performed between indoor air flowing from the first exhaust room to the second exhaust room and outdoor air flowing from the first air supply room to the second air supply room. In the device,
The ventilation device includes at least one operation mode for controlling the state of indoor air, and when the ventilation device is operated, a purge mode for discharging the air inside the ventilation device to the outside is set prior to the operation mode. carried out until satisfaction,
The purge mode is a ventilation device, characterized in that it is configured to discharge the air inside the ventilation device to the outside using the indoor air flowing in through the second air supply chamber and the indoor air flowing in through the first exhaust chamber. delete According to claim 1,
The set condition is set when a set time elapses or when the air quality concentration value sensed in the supply side indoor air flow path or inside the ventilation device satisfies a set target air quality concentration value range. According to claim 1,
Further comprising a second damper for opening and closing the flow path of the air exhausted from the second exhaust chamber to the outside,
In the purge mode, the ventilation device, characterized in that the second damper is opened. 5. The method of claim 4,
Further comprising a third damper for opening and closing the flow path of the air flowing into the first air supply chamber,
In the purge mode, the third damper is a ventilation device, characterized in that closed. 5. The method of claim 4,
Further comprising: a first damper for opening and closing a flow path of air introduced into the first exhaust chamber; and a fourth damper for opening and closing a flow path of air supplied from the second air supply chamber to the room;
In the purge mode, at least one of the first damper and the fourth damper is opened. delete A first exhaust chamber into which indoor air is introduced, a second exhaust chamber for discharging indoor air passing through the first exhaust chamber to the outdoors, a first air supply chamber into which outdoor air flows, and outdoor air passing through the first air supply chamber. Ventilation comprising a second air supply room for supplying air into the room, and a total heat exchanger in which heat exchange is performed between indoor air flowing from the first exhaust room to the second exhaust room and outdoor air flowing from the first air supply room to the second air supply room. In the device,
The ventilation device includes at least one operation mode for controlling the state of indoor air, and when the ventilation device is operated, a purge mode for discharging the air inside the ventilation device to the outside is set prior to the operation mode. carried out until satisfaction,
A first damper for opening and closing a flow path of air introduced into the first exhaust chamber, a second damper for opening and closing a flow path of air exhausted from the second exhaust chamber to the outside, and the air flowing into the first air supply chamber A counterwind prevention damper for opening and closing the flow path, and a fourth damper for opening and closing the flow path of air supplied from the second air supply chamber to the room,
In the purge mode, the second damper and the headwind prevention damper are opened, and at least one of the first damper and the fourth damper is opened. 9. The method of claim 1 or 8,
and an exhaust blower for forcibly exhausting air from the second exhaust chamber to the outside;
In the purge mode, the ventilation device, characterized in that the blower for exhaust operation. 10. The method of claim 9,
A bypass passage is formed on one side of the first exhaust chamber, the second exhaust chamber, the first air chamber, the second air chamber and the total heat exchanger with a diaphragm therebetween,
In the partition plate, a first communication port connecting the first exhaust chamber and the bypass passage, a second communication port connecting the second exhaust chamber and the bypass passage, and the first air supply chamber and the bypass passage connecting the bypass passage A third communication port is formed,
A fifth damper for opening and closing the first communication port, and a sixth damper for opening and closing the third communication port,
In the purge mode, the fifth damper is selectively opened and closed, the ventilation device, characterized in that the sixth damper is opened. 11. The method of claim 10,
and an eighth damper for opening and closing an air flow path connecting the second air supply chamber and the second exhaust chamber,
In the purge mode, the ventilation device, characterized in that the eighth damper is opened. 11. The method of claim 10,
A fourth communication hole connecting the second air supply chamber and the bypass passage is formed in the diaphragm,
It includes a seventh damper for opening and closing the fourth communication port,
In the purge mode, the ventilation device, characterized in that the seventh damper is opened. 13. The method of claim 12,
and an eighth damper for opening and closing an air flow path connecting the second air supply chamber and the second exhaust chamber,
In the purge mode, the ventilation device, characterized in that the eighth damper is opened. 9. The method of claim 1 or 8,
The air supply passage connected to the second air supply chamber or the second air supply chamber is provided with a plasma ion generator for sterilizing the supplied air. 9. The method of claim 1 or 8,
The purge mode is a ventilation device, characterized in that performed when the initial installation of the ventilation device.

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