KR102029712B1 - Heat Exchanger - Google Patents

Abstract

The present invention relates to a heat exchanger for firefighting and, more specifically, to a heat exchanger for firefighting, wherein an air supply fan unit provided with a sirocco fan having excellent air supply and exhaust efficiency and an air exhaust fan unit are loaded for outdoor air to flow to the inside. Moreover, indoor air is exhausted to the outside to increase circulation efficiency of the indoor air. The air supply fan unit and the air exhaust fan unit are configured to simultaneously discharge the indoor air to the outside in case of fire. Accordingly, toxic gas created by the fire can be rapidly exhausted to secure safety in firefighting.

Description

Heat Exchanger {Heat Exchanger}

The present invention relates to a fire-fighting heat exchanger, and more particularly, an air supply fan unit and an exhaust fan unit provided with a sirocco fan having excellent air supply and exhaust efficiency in the main body to introduce external air into the room, Exhaust to the outside to increase the circulation efficiency of the indoor air, and in the event of a fire, both the supply fan unit and the exhaust fan unit are configured to discharge the indoor air to the outside at the same time to ensure the safety of fire by quickly exhausting the toxic gas caused by the fire It relates to a fire heat exchanger.

As the use of energy increases today, buildings are being designed that actively seek energy savings.

In the energy-saving building as described above, since moisture and polluted air generated indoors do not escape to the outside and outdoor air is not easily introduced into the indoor air, various dusts, bacteria, harmful gases, odors, etc. may exist in the indoor air. Can

Such indoor air quality may be about 2 to 10 times more harmful to human body than outdoor air.In order to improve the quality of indoor air, if the windows of the building are periodically opened and ventilated, the heat of the room may escape to the outside. Energy loss inevitably occurs.

The electric heat exchanger developed to solve this problem is sensible between indoor air and outdoor air in the process of discharging indoor air and supplying outdoor air to improve indoor air quality while preventing energy loss. It is a device for exchanging total heat including heat and latent heat.

Ventilation of indoor air through such a heat exchanger has the advantage of minimizing indoor heat loss, and recent installations have been made universally in each building.

 In case of fire in the indoor space, a large amount of toxic gas is generated, and the generated toxic gas shortens the golden time due to evacuation, which causes many casualties.

Background Art A conventional heat exchanger is provided with a sirocco type air supply fan unit and a sirocco type exhaust fan unit which rotate the sirocco fan member in one direction to provide air supply or exhaust. The sirocco type has the advantage of having a relatively higher air supply capacity and less noise than the propeller fan.

However, the sirocco fan member, in contrast to the propeller fan, the blowing direction is not changed by simply changing the rotation direction in the forward and reverse, and the blowing performance required only when rotated in one direction can be exhibited.

That is, since the sirocco fan member is configured to intake air and supply air only in one direction in structure, even when the sirocco fan member is rotated in the reverse direction by changing the rotation direction like the propeller fan member, the blowing direction is not changed. It has a characteristic that it is difficult to satisfy the required blowing amount.

KR 10-1072145 B1 KR 10-1263656 B1 KR 20-2018-0002680 U

An object of the present invention devised to solve the above problems is to install an air supply fan unit and an exhaust fan unit having a sirocco fan having excellent air supply and exhaust efficiency in the main body to introduce outdoor air into the room, and to provide indoor air. Exhaust air to increase the circulation efficiency of indoor air, and in the event of a fire, both the supply fan unit and the exhaust fan unit discharge indoor air at the same time to ensure the safety of fire by quickly exhausting the toxic gas caused by the fire. The present invention provides a fire-fighting heat exchanger.

The above object is achieved by the following configuration provided in the present invention.

Fire heat transfer device according to the invention,

A storage main body having an air supply port including an outdoor air inlet port and an outdoor air air supply port, and a storage space in which an exhaust path including an indoor air inlet port and an indoor air exhaust port is formed;

An air supply fan unit which is formed in a storage space of the storage main body, and intakes outdoor air along the air supply air and supplies the intake outdoor air to the indoor space along the indoor air supply pipe;

An exhaust fan unit which is accommodated in an accommodation space of the accommodation body, and intakes indoor air along an indoor exhaust pipe and exhausts the intaken indoor air to the outside along an exhaust path;

An electrothermal heat exchanger formed on an air supply path and an exhaust path formed in the accommodation space of the accommodation body and exchanging heat between the external air supplied to the interior along the supply path and the indoor air exhausted to the outside along the exhaust path; And

A control unit for controlling the driving of the air supply fan unit and the exhaust fan unit,

The air supply fan unit may be configured to selectively perform an air supply action of supplying outdoor air to the room along the air supply by changing the air supply exhaust direction under control of a controller, and an exhaust operation of exhausting indoor air to the outside along the air supply. Composed,
An auxiliary exhaust pipe is formed on the air supply path in which the air supply fan unit is disposed, and the first damper unit and the second damper unit are configured to switch the air supply and exhaust direction by the air supply fan unit of the air supply line and the auxiliary exhaust pipe on the auxiliary exhaust pipe and the air supply line. This arrangement is characterized in that the supply and exhaust direction by the air supply fan unit is switched by the selective shielding action of the first damper unit and the second damper unit.

Preferably, the air supply fan unit includes a blower case each having an intake port and an air supply port, and a sirocco fan member disposed in the blower case in a rotational structure to intake air through the intake port and discharge it through the air supply port, and the sirocco An air supply fan unit including an electric motor for rotating the fan member in one direction;

The isometric rotation unit is further configured to rotate the air supply fan unit in a forward and backward direction so as to replace the intake port and the air supply port formed in the air blowing case with the connection head formed in the air supply pipe.

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And, further comprising a fire detection sensor unit for detecting a fire in the indoor space,

The control unit drives the air supply fan unit and the exhaust fan unit at the same time when a fire in the indoor space is detected through the topic detection sensor unit, and changes the air supply direction of the air supply fan unit so that the air supply fan unit together with the exhaust fan unit And to perform the flue gas intake and exhaust to the outside.

Firefighting heat transfer device proposed in another embodiment of the present invention,

A storage main body having an air supply port including an outdoor air inlet port and an outdoor air air supply port, and a storage space in which an exhaust path including an indoor air inlet port and an indoor air exhaust port is formed;

An air supply fan unit formed in the accommodation space of the accommodation body and configured to intake outdoor air along the air supply and to supply the intaked outdoor air to the indoor space through an indoor air supply pipe;

An exhaust fan unit which is accommodated in an accommodation space of the accommodation body and intakes indoor air along an exhaust path, and intakes indoor air intakes along an indoor exhaust pipe to exhaust the outdoor air;

An electrothermal heat exchanger formed on an air supply path and an exhaust path formed in the accommodation space of the accommodation body and exchanging heat between the external air supplied to the room along the air supply path and the indoor air exhausted to the outside along the exhaust path;

An auxiliary exhaust pipe configured to bypass the indoor air supply pipe and communicate with the air supply pipe;

An auxiliary exhaust fan unit disposed in the auxiliary exhaust pipe to intake air through the auxiliary exhaust pipe, supply air along the air supply, and discharge the air to the outside;

A first damper unit disposed at an exhaust port of the air supply fan unit to open and close the indoor air supply pipe and the air supply fan unit;

A second damper unit for opening and closing between the indoor air supply pipe and the auxiliary exhaust pipe; And

And a control unit for controlling driving of the air supply fan unit, the exhaust fan unit, the auxiliary exhaust fan unit, the first damper unit, and the second damper unit.

As described above, in the present invention, the heat exchanger disposed in communication with each room is improved, and in general, the outside air is introduced into the room, and the ventilation is performed to discharge the indoor air to the outside. By evacuating the exhaust gas, the fire is delayed while minimizing the residual amount of toxic gas remaining in the indoor space at the beginning of the fire, thereby ensuring sufficient evacuation time.

In addition, the present invention is to be driven in conjunction with the fire detection sensor unit, and in particular by implementing a heat exchanger adopting a sirocco fan type air supply fan unit and an exhaust fan unit having a stable supply and exhaust efficiency, it is possible to ensure a stable flue efficiency have.

Accordingly, the present invention adopts a sirocco fan type air supply fan unit having excellent blowing efficiency, and if the exhaust of the indoor air such as a fire is required, the air flow direction of the air supply fan unit is switched, thereby allowing the indoor air through the exhaust fan unit and the air supply fan unit. Simultaneous exhaust of air can be achieved.

In addition, in the present invention, dehumidification of the heat exchange unit is possible through the exhaust action of the exhaust fan unit and the auxiliary exhaust fan unit.

In particular, the indoor air supply pipe dehumidifies the heat exchanger by inhaling air required for dehumidification of the heat exchanger in the installation space without utilizing the indoor air supply pipe that is a path for supplying external air to the indoor space. Contamination is prevented.

Figure 1 shows the overall configuration of the total heat exchanger proposed in the preferred embodiment of the present invention,
Figure 2 shows a detailed configuration, an isometric rotation state of the air supply fan unit in the total heat exchange apparatus proposed in the preferred embodiment of the present invention,
3 and 4 is a working state of the heat exchanger proposed in the preferred embodiment of the present invention (Fig. 3 shows the exhaust state through the exhaust fan unit and the air supply state through the supply fan unit, Figure 4 is an exhaust fan unit Shows the simultaneous exhaust state through the supercharge fan unit),
5 to 7 is a functional state diagram of the electrothermal heat exchanger proposed as a preferred embodiment in the present invention (Fig. 5 shows the exhaust state through the exhaust fan unit and the air supply state through the supply fan unit, Figure 6 is an exhaust fan FIG. 7 illustrates a simultaneous exhaust state through the unit and the auxiliary exhaust fan unit, and FIG. 7 illustrates a dehumidification state of the total heat exchange unit through the exhaust fan unit and the auxiliary exhaust fan unit.

Hereinafter, with reference to the accompanying drawings will be described in detail the electrothermal exchange device proposed in the preferred embodiment of the present invention.

Figure 1 shows the overall configuration of the total heat exchanger proposed as a preferred embodiment in the present invention, Figure 2 is a detailed configuration, isometric, of the air supply fan unit in the total heat exchanger proposed in the preferred embodiment of the present invention 3 and 4 show the operating state of the electrothermal heat exchanger proposed as a preferred embodiment of the present invention (FIG. 3 shows an exhaust state through an exhaust fan unit and an air supply state through an air supply fan unit, 4 is a view showing a simultaneous exhaust state through the exhaust fan unit and the supply fan unit), Figures 5 to 7 is an operational state diagram of the electrothermal heat exchanger proposed as a preferred embodiment in the present invention (FIG. Exhaust through the exhaust fan unit and supply state through the air supply fan unit, Figure 6 is a simultaneous exhaust state through the exhaust fan unit and the auxiliary exhaust fan unit Will show, the Figure 7 shows the dehumidification will state unit total heat exchange with the exhaust fan unit and the auxiliary exhaust fan unit).

The electrothermal heat exchanger 1 proposed as a preferred embodiment of the present invention is an air supply including an outdoor air inlet 11a and an outdoor air air supply 11b as shown in FIGS. 11) and an accommodating body 10 having an accommodating space in which an exhaust passage 12 including an indoor air inlet 12a and an indoor air exhaust port 12b is formed; An air supply fan unit 20 formed in the accommodation space of the accommodation body 10 to intake the outdoor air along the air supply 11 and supply the outdoor air to the indoor space through the indoor air supply pipe P1; and; An exhaust fan unit 30 which is accommodated in the storage space of the accommodation body 10 and intakes indoor air through an indoor exhaust pipe P2 and exhausts the intake indoor air to the outside along the exhaust path 12; ; Is formed on the air supply passage 11 and the exhaust passage 12 formed in the storage space of the receiving body 10, the outside air to be supplied to the room along the air supply passage 11, along the exhaust passage 12 An electrothermal heat exchanger 40 for exchanging indoor air exhausted to the outside; And a controller 50 for controlling the driving of the air supply fan unit 20 and the exhaust fan unit 30.

The electrothermal heat exchanger 1 configured as described above attempts to ventilate each indoor space through each outdoor air air supply member communicating with the air supply passage 11 and each outdoor air intake member communicating with the exhaust passage 12. .

In this process, the electrothermal heat exchanger 1 exchanges the external air supplied to the indoor space through the air supply 11 and the indoor air discharged to the outside through the exhaust passage 12 to enter the indoor space. The temperature deviation between the outside air and the air remaining in the room is suppressed.

Since the main configuration and operation of the electrothermal exchange device 1 is well known in the art, detailed description thereof is omitted herein.

However, in the present invention, when the fire occurs, the air supply fan unit 20 does not supply external air through the air supply 11, and is configured to exhaust the indoor air to the outside, thereby generating in the indoor space by the fire. Promote the rapid discharge of toxic gases so that early fire evacuation is possible.

First, in the first embodiment of the present invention, as shown in FIGS. 1 to 4, the air supply and exhaust direction of the air supply fan unit 20 is switched, and the air supply is normally performed to supply external air to the indoor space, and then fire When generated, it is to perform the exhaust action, that is, the exhaust action to discharge the indoor air to the outside.

In the second embodiment of the present invention, an auxiliary exhaust fan unit, a damper unit, and an auxiliary exhaust pipe are organically added to perform an air supply function to normally supply external air to the indoor space, and then discharge the indoor air to the outside during a fire. To perform the exhaust action, that is, the flue gas action.

In particular, in the present embodiment, the air supply fan unit 20 is equipped with a sirocco fan member which does not adopt a propeller fan member whose air supply direction is simply changed through forward and reverse rotation, and allows air intake in a large amount through one direction rotation and has a low noise. ) Is adopted.

That is, the air supply fan unit 20 according to the present embodiment includes an air intake port 21 a and an air intake port 21 a and an air inlet port 21 b, respectively, and a rotation structure in the air intake port 21. And a sirocco fan 22 for inhaling air through the air supply port 21b and an electric motor 23 for rotating the sirocco fan member 22 in one direction.

By the way, the sirocco fan member 22 has a rotational direction unlike the propeller fan member in view of its characteristics.

That is, when the sirocco fan member 22 disposed in the blower case 21 rotates in one direction, strong blowing performance is exhibited. Blowing performance

Therefore, in the art, unlike the propeller type air supply fan unit and the exhaust fan unit, the sirocco air supply fan unit 20 and the exhaust fan unit to which the sirocco fan member 22 is applied are exclusively used for intake or exhaust. It is true.

In detail, the sirocco fan member 22 is configured to intake air and supply air only in one direction in structure, and rotates the sirocco fan member in the reverse direction by changing the rotational direction of the electric motor 23 like the propeller fan. Even if it does, the blowing direction is not changed or it is difficult to meet the required blowing amount.

Accordingly, in the present invention, the sirocco fan member 22 is mounted to adopt a sirocco fan type air supply fan unit 20 having an excellent air supply capacity, and the connection direction between the air supply fan unit 20 and the air supply line 11 is changed. In other words, the air supply fan unit 20 is configured to supply air to the outdoor air in normal times, and in the event of a fire, the exhaust gas, that is, the exhaust gas, is discharged to the outside.

To this end, in the present embodiment, the connection head 11c for selectively connecting the intake port 21a and the air supply port 21b of the sirocco fan type air supply fan unit 20 is formed on the air supply 11, The air supply fan unit 20 includes a conformal rotation part 24 which is rotated isotropically in forward and reverse directions so as to replace the intake port 21a and the air supply port 21b by connecting to the air supply 11.

Here, the conformal pivot 24 may be adopted in various forms such as an electric motor, a conformal cylinder, a solenoid.

Referring to FIG. 2 showing a preferred embodiment, the blower case 21 is formed in a spherical shape, and is connected to the head 11c formed on the air supply 11 by forward and reverse rotation by the driving of the conformal pivoting unit 24. The intake port 21a and the air supply port 21b are selectively substituted to be connected.

At this time, a sealing ring 11d made of an elastic material is disposed in the connection head 11c formed on the air supply 11, and an air intake port 21a and an air supply port 21b formed in the blower case 21 are provided. Through the sealing ring (11d) to be in close contact with the connection head (11c) formed in the air supply (11) to be sealed.

Accordingly, the air supply fan unit 20 has an air supply function for supplying external air to the room along the air supply 11 by changing the air supply direction under the control of the controller 50, and the indoor air along the air supply 11. It may be possible to perform the exhaust function to exhaust the outdoor.

And, when a fire occurs, the control unit 50 rotates the sirocco fan type air supply fan unit 20 isometrically through the isometric pivoting unit 24 as shown in FIGS. 2B and 4 to change the air supply and exhaust direction of the air supply fan unit 20. In addition, the air supply fan unit 20 performs the exhaust gas exhaust function to intake indoor air together with the exhaust fan unit 30 to exhaust the air.

At this time, further comprising a fire detection sensor unit 60 for detecting a fire in the indoor space, the control unit 50, if the fire of the indoor space is detected through the fire detection sensor unit 60, the air supply fan unit 20 And the exhaust fan unit 30 are driven, respectively, and as shown in FIGS. 2B and 4, the air supply fan unit 20 is rotated to change the supply and exhaust direction of the air supply fan unit 20 so that the air supply fan unit 20 is rotated. Together with the exhaust fan unit 30, the indoor air is inhaled to perform the exhaust gas exhaust function to the outside.

And, by adding a humidity measuring sensor unit 70 for detecting the residual humidity of the total heat exchanger 40, if the humidity of the total heat exchanger 40 measured through the humidity measuring sensor unit 70 is higher than the set humidity. In the same manner as in the case of a fire, through the air supply fan unit 20 and the exhaust fan unit 30 to exhaust the indoor air to the outside to achieve dehumidification of the heat exchange unit 40, which is also within the scope of the present invention Scheduled.

Meanwhile, in another embodiment of the present invention, as shown in FIGS. 5 to 7, the auxiliary exhaust pipe 80 communicating between the indoor air supply pipe P1 communicating with the air supply fan unit 20 and the air supply passage 11 is provided. Add, and further arrange the auxiliary exhaust fan unit 90 on the auxiliary exhaust pipe (80).

The first damper unit 81 is disposed in the exhaust port 21b of the air supply fan unit 20, and the second damper unit 82 is disposed between the indoor air supply pipe P1 and the auxiliary exhaust pipe 80. To place.

Thus, as shown in FIG. 5, the controller 50 discharges the indoor air remaining in the indoor space through the exhaust path unit P2 to the outside through the exhaust path 12 as shown in FIG. 5. At the same time, the first damper unit 81 is opened, the second damper unit 82 is closed, and then the air supply fan unit 20 is driven to supply the air supply 11 by the air supply action of the air supply fan unit 20. Accordingly, the outside air taken into the air is supplied to each indoor space through the indoor side air supply pipe (P1).

And, in the event of a fire, as shown in FIG. 6, the controller 50 passes the indoor air remaining in the indoor space to the outside along the exhaust path 12 through the indoor exhaust pipe P2 through the exhaust fan unit 30. Simultaneously with discharging, the first damper unit 81 is closed, the second damper unit 82 is opened, and the auxiliary exhaust fan unit 90 is driven to exhaust the auxiliary exhaust fan unit 90. Through the air supply pipe (P1) so that the indoor air intake in each indoor space is discharged to the outside through the air supply (11).

Thus, the heat exchanger 1 'according to the present embodiment normally supplies air to the outside space through the air supply fan unit 20 to the indoor space, and the indoor air to the outside through the exhaust fan unit 30. By performing the air circulation action including the exhaust action to exhaust, the heat transfer between the indoor air and the outside air is exchanged.

In the event of a fire, the exhaust fan unit 30 and the auxiliary exhaust fan unit 90 remain in each indoor space through the indoor air supply pipe P1 and the indoor exhaust pipe P2 communicating with each indoor space. By discharging the indoor air to the outside, the toxic gases remaining in the indoor space by the fire is discharged more quickly.

Therefore, the electrothermal heat exchanger 1 ′ according to the present embodiment can perform a more stable flue gas action through the exhaust fan unit 30 and the auxiliary exhaust fan unit 90 when a fire occurs.

In addition, in the present embodiment, when the humidity of the predetermined value or more is sensed by the heat exchanger unit 40, air is circulated and discharged to the heat exchanger unit 40 through the exhaust fan unit 30 and the auxiliary exhaust fan unit 90. Thus, dehumidification of the total heat exchange part 40 is achieved by the air discharged circulating.

To this end, in the present embodiment, the humidity measurement sensor unit 70 for detecting the humidity of the heat exchange unit 40 is added.

In particular, the auxiliary exhaust fan unit 90 is installed in the heat exchanger (1 ') is installed without the intake of indoor air in the indoor space through the indoor air supply pipe (P1) during the dehumidification process of the heat exchanger (40). By taking in air in the space S and discharging it along the heat exchanger 40, the humidity remaining in the heat exchanger 40 is dehumidified by the air sucked in the installation space.

With this configuration, contamination of the indoor side air supply pipe P1 due to the intake of the indoor air remaining in the indoor space for the dehumidification to the air supply 12 may be prevented.

To this end, in this embodiment, as shown in FIG. 7, an installation space intake port 80a communicating with the installation space S in which the heat exchange device 1 'is installed is formed on the auxiliary exhaust pipe 80. A third damper unit 83 is disposed in the installation space intake port 80a.

Therefore, when the humidity is detected by the humidity measuring sensor unit 70 or more than the set value in the heat exchange unit 40, the controller 50 drives the exhaust fan unit 30 to follow the indoor exhaust pipe (P2). The indoor air that is inhaled in the indoor space is discharged through the heat exchange unit 40.

At the same time, the controller 50 closes the first damper unit 81 and the second damper unit 82, opens the third damper unit 83, and drives the auxiliary exhaust fan unit 90.

Accordingly, the air in the installation space S is supplied into the electrothermal heat exchanger 40 through the installation space intake port 80a formed in the auxiliary exhaust pipe 80 and exhausted, and as a result, the installation space intake port 80a is opened. And dehumidification of the heat exchanger part 40 by the air sucked in the installation space S by the auxiliary exhaust fan unit 90, the electrothermal heat exchanger 1 'according to the present embodiment is an exhaust fan unit ( Dehumidification of the total heat exchange part 40 is possible through the exhaust action of the 30 and the auxiliary exhaust fan unit 90.

In particular, during the dehumidification process of the heat exchanger 40, the heat exchanger 40 intakes air in the installation space S without utilizing the indoor air supply pipe P1, which is a path for supplying external air to the indoor space. Since it dehumidifies, contamination of the indoor side air supply pipe P1 due to dehumidification is prevented.

1, 1 '. Heat exchanger
10. Storage body 11. By air supply
11a. Outdoor air inlet 11b. Outdoor air supply
11c. Head of Connection 11d. Sealing ring
12. Exhaust Furnace 12a. Indoor air inlet
12b. Indoor air exhaust
20. Air supply fan unit (sirocco fan type) 21. Blowing case
21a. Intake port 21b. Air supply port
22. Sirocco fan member 23. Electric motor
24. Isometric pivot
30. Exhaust fan unit (sirocco fan type) 40. Heat exchanger
50. Control unit 60. Fire detection sensor unit
70. Humidity measurement sensor unit
80. Auxiliary exhaust pipes 80a. Installation Intake Port
81. First Damper Unit
82. 2nd damper unit 83. 3rd damper unit
90. Auxiliary Exhaust Fan Unit
P1. Indoor air supply piping P2. Indoor exhaust piping
S. Installation Space

Claims (5)

A storage main body having an air supply port including an outdoor air inlet port and an outdoor air air supply port, and a storage space in which an exhaust path including an indoor air inlet port and an indoor air exhaust port is formed;
An air supply fan unit which is formed in a storage space of the storage main body, and intakes outdoor air along the air supply air and supplies the intake outdoor air to the indoor space along the indoor air supply pipe;
An exhaust fan unit which is accommodated in an accommodation space of the accommodation body, and intakes indoor air along an indoor exhaust pipe and exhausts the intaken indoor air to the outside along an exhaust path;
An electrothermal heat exchanger formed on an air supply path and an exhaust path formed in the accommodation space of the accommodation body and exchanging heat between the external air supplied to the interior along the supply path and the indoor air exhausted to the outside along the exhaust path; And
A control unit for controlling the driving of the air supply fan unit and the exhaust fan unit,
The air supply fan unit may be configured to selectively perform an air supply action of supplying outdoor air to the room along the air supply by changing the air supply exhaust direction under control of a controller, and an exhaust operation of exhausting indoor air to the outside along the air supply. Composed,
An auxiliary exhaust pipe is formed on the air supply path in which the air supply fan unit is disposed, and the first damper unit and the second damper unit are configured to switch the air supply and exhaust direction by the air supply fan unit of the air supply line and the auxiliary exhaust pipe on the auxiliary exhaust pipe and the air supply line. And is arranged such that the direction of supply / exhaust by the supply fan unit is switched by the selective shielding action of the first damper unit and the second damper unit. The air supply fan unit of claim 1, wherein the air supply fan unit comprises: a blower case each having an intake port and an air supply port, and a sirocco fan member disposed in the blower case in a rotational structure to intake air through the intake port and discharge the air through the supply port; And an electric motor for rotating the sirocco fan member in one direction,
And an isometric pivoting unit configured to conformally rotate the air supply fan unit in the forward and reverse directions so as to replace the intake port and the air supply port formed in the blower case with the connection head formed by the air supply. delete According to claim 1 or 2, further comprising a fire sensor unit for detecting a fire in the indoor space,
The control unit drives the air supply fan unit and the exhaust fan unit at the same time when a fire in the indoor space is detected through the topic detection sensor unit,
And the air supply unit of the air supply fan unit is configured to change the air supply direction so that the air supply fan unit intakes indoor air together with the exhaust fan unit to exhaust the air to the outside. A storage main body having an air supply port including an outdoor air inlet port and an outdoor air air supply port, and a storage space in which an exhaust path including an indoor air inlet port and an indoor air exhaust port is formed;
An air supply fan unit formed in the accommodation space of the accommodation body and configured to intake outdoor air along the air supply and to supply the intaked outdoor air to the indoor space through an indoor air supply pipe;
An exhaust fan unit which is accommodated in an accommodation space of the accommodation body and intakes indoor air along an exhaust path, and intakes indoor air intakes along an indoor exhaust pipe to exhaust the outdoor air;
An electrothermal heat exchanger formed on an air supply path and an exhaust path formed in the accommodation space of the accommodation body and exchanging heat between the external air supplied to the room along the air supply path and the indoor air exhausted to the outside along the exhaust path;
An auxiliary exhaust pipe configured to bypass the indoor air supply pipe and communicate with the air supply pipe;
An auxiliary exhaust fan unit disposed in the auxiliary exhaust pipe to intake air through the auxiliary exhaust pipe, supply air along the air supply, and discharge the air to the outside;
A first damper unit disposed at an exhaust port of the air supply fan unit to open and close the indoor air supply pipe and the air supply fan unit;
A second damper unit for opening and closing between the indoor air supply pipe and the auxiliary exhaust pipe; And
And a control unit for controlling the driving of the air supply fan unit, the exhaust fan unit, the auxiliary exhaust fan unit, the first damper unit, and the second damper unit.

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