KR20170103133A - Ventilator - Google Patents

Abstract

The purpose of the present invention is to provide a ventilator which is effective in preventing condensation occurring inside and outside of equipment, provides ventilation sufficient to the number of people in an indoor environment, is able to maximize energy efficiency, and positively pressurizes the indoor environment, thereby preventing any contamination from the outside. For embodying stated purposes, the present invention comprises: a first exhaust chamber (10); a second exhaust chamber (20); a first air supply chamber (30); a second air supply chamber (40); and a bypass passage (70) on one side of a heat exchanger (50), wherein a partition (60) is disposed between the bypass passage (70) and the heat exchanger (50). The bypass passage (70) in a bypass mode provides a flow path through which indoor air inputted to the first exhaust chamber (10) flows towards the second exhaust chamber (20) without passing the heat exchanger (50). In an air purifying mode, the bypass passage (70) provides a flow path through which the entire indoor air inputted to the first exhaust chamber (10) flows towards the first air supply chamber (30). In a condensation control mode, the bypass passage (70) provides a flow path through which the entire or a part of the indoor air inputted to the first exhaust chamber (10) flows towards the first air supply chamber (30) to be mixed with outdoor air inputted and supplied to the first air supply chamber (30).

Description

Ventilator {VENTILATOR}

The present invention relates to a ventilator, and more particularly, to a ventilator that mixes and recirculates air introduced into the room from the outside to the room, thereby preventing condensation from occurring inside and outside the equipment, The present invention relates to a ventilation apparatus capable of maximizing efficiency and particularly capable of keeping the room at a positive pressure at all times to prevent contamination from the outside.

In general households and offices, there is installed a cooling and heating device to perform indoor cooling and heating according to the seasonal changes. Such a cooling and heating device includes an air conditioner for cooling and heating the indoor air by cooling and heating the indoor air , And boilers.

Since the indoor air such as a general home and office where the air conditioner and the heating device are installed is maintained in a hermetically closed state in order to improve the cooling and heating efficiency, Odor is generated or foreign matter such as dust becomes floating. Accordingly, the room air is ventilated every predetermined time to remove the odor or dust from the room. It is necessary to ventilate the contaminated room air to the outside while maintaining the room temperature, and to ventilate the fresh outdoor air to the room Device is used.

Generally, when the outside wall is installed in an insulated space in an apartment or a building, condensation may be minimized inside the ventilation unit. However, when the outside wall of the building is installed in an unheated space, Condensation occurs in the inside of the ventilation apparatus due to a condition substantially similar to that of the outdoor space.

That is, when the outdoor air temperature is low as in winter, the temperature of the space where the ventilator is installed is also lowered. If the ventilator is not used for a long time, condensation will occur inside the ventilator.

In order to prevent condensation from occurring in a ventilator, conventionally, an exhaust fan is sucked into the room by sucking in indoor air, or a heater is installed inside the ventilator to remove condensation by heat generated by the heater Respectively.

However, if the exhaust fan is operated for a certain period of time, the indoor pressure becomes negative pressure, so that contaminated and cold outdoor air can be mixed into the room, and condensation can be prevented only in a passage where room air flows to the outside, There is a limit in which condensation can not be prevented. When the condensation is removed by the heat generated by the heater, there is a problem that consumption of electric energy is increased.

As a prior art related to a ventilation device for preventing the occurrence of condensation, Japanese Patent No. 10-1162973 (a heat recovery type ventilation device provided with a dehumidifying function) is provided with an outdoor air inflow passage and an indoor air vent passage And a dehumidifying function is performed by bypassing the indoor air introduced into the discharge passage to the inflow passage side of the outdoor air by opening the damper and recirculating the indoor air to the indoor side.

However, since the damper is provided on the side wall of the ventilator, the volume of the ventilator is increased in order to secure the space for installing the damper, and the flow path through which the indoor air is recirculated is limited, There is a problem in that condensation can not be prevented over the entire area of the condenser.

On the other hand, there is a bypass type ventilator for performing outside air cooling in the conventional ventilator. This is configured such that heat exchange is not performed between exhausted indoor air and outdoor air to be supplied, so that outdoor air is cooled so that outdoor air is directly introduced into the indoor space, thereby reducing indoor temperature to a certain level. When the bypass mode is not used, air stagnates in the bypass passage, causing air pollution as well as dew condensation. As a result, There is a problem that it causes breeding.

On the other hand, Japanese Patent Application No. 10-0577252 discloses an air cleaning and ventilation system having an air cleaning function and a ventilation function. However, since the ventilation system and the air cleaning apparatus are separately constructed, have.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to effectively prevent the occurrence of condensation inside and outside the apparatus, sufficiently satisfy the required ventilation amount of indoor personnel and maximize energy efficiency, And it is an object of the present invention to provide a ventilating apparatus which can keep the room at a positive pressure and prevent contamination from the outside.

In order to achieve the above object, the ventilator (1) of the present invention includes a first exhaust chamber (10) through which indoor air flows, and a second exhaust chamber (10) through which indoor air passed through the first exhaust chamber A second air supply room (40) for supplying outdoor air via the first air supply room (30) to the room, and a second air supply room A total enthalpy heat exchanger 50 in which heat exchange is performed between indoor air flowing from the first exhaust chamber 10 to the second exhaust chamber 20 and outdoor air flowing from the first feed chamber 30 to the second feed chamber 40, Wherein one end of the first exhaust chamber (10), the second exhaust chamber (20), the first feed chamber (30), the second feed chamber (40), and the total enthalpy heat exchanger (50) The bypass passage 70 is formed in the first exhaust chamber 10 in the bypass mode and the indoor air introduced into the first exhaust chamber 10 flows through the total enthalpy heat exchanger 50 ) And a flow path through which all of the room air introduced into the first exhaust chamber 10 flows toward the first air supply chamber 30 is provided in the air clean mode In the condensation control mode, all or a part of the room air introduced into the first exhaust chamber (10) is mixed with the outdoor air to be supplied to the first air supply room (30) ) Of the flow path.

The first exhaust chamber 10 is provided with a first communication hole 10a formed in the partition plate 60 so as to communicate with the bypass passage 70 and a passage through which the room air flows toward the total enthalpy heat exchanger 50 A second communication hole 20a formed in the partition plate 60 to communicate with the bypass passage 70 and a second communication hole 20b formed in the partition plate 60 to communicate with the bypass passage 70, A bypass damper 22 for opening and closing the two communication ports 20a and an exhaust damper 23 for opening and closing a passage through which the indoor air introduced into the second exhaust chamber 20 is exhausted to the outside, The first class chamber 30 is provided with a third communication hole 30a formed in the partition plate 60 so as to communicate with the bypass passage 70 and a mixing damper 32 for opening and closing the third communication hole 30a. And an air supply damper 33 for opening and closing a passage through which outdoor air flows into the first air supply chamber 30.

In the air cleaning mode, the mixing damper 32 is opened, the air cleaning damper 12, the bypass damper 22, the exhaust damper 23, and the air supply damper 33 are closed and the air supply fan 43 may be driven.

In the dew condensation control mode, the air cleaning damper 12, the exhaust damper 23, the mixing damper 32 and the air supply damper 33 are opened, the bypass damper 22 is closed, 25 and the air supply fan 43 may be driven.

The first exhaust chamber 10 is provided with a first temperature sensor 13 and a second humidity sensor 14 for measuring the dew point of the indoor air and the second air supply chamber 40 is supplied with air And a second temperature sensor 42 for measuring the temperature of the outdoor air. When the temperature measured by the second temperature sensor 42 is lower than the dew point of the indoor air, the mixing damper 32 is opened And the number of revolutions of the air supply fan 43 is increased.

The first exhaust chamber 10 is provided with a dew point temperature sensor 15 for measuring the dew point of indoor air and the second air supply chamber 40 is provided with a dew point temperature sensor 15 for measuring the temperature of outdoor air The second damper 32 is opened when the temperature measured by the second temperature sensor 42 is lower than the dew point of the indoor air and the temperature of the air supplied from the air supply fan 43 The number of revolutions can be controlled to be increased.

The second exhaust chamber 20 is provided with a second humidity sensor 24 for measuring the humidity of the indoor air to be exhausted. When the humidity measured by the second humidity sensor 24 exceeds the set humidity value The mixing damper 32 is opened and the number of rotations of the air supply fan 43 is controlled to increase.

The mixing damper 32 includes a rotation shaft 32a arranged so as to be orthogonal to a flow direction of the room air passing through the third communication hole 30a and a second communication hole 32b which is rotated about the rotation axis 32a, A damper plate 32b that opens and closes the damper plate 32b and a surface heat emission element 32c attached to the outdoor air introduction side surface of the damper plate 32b, And a moisture sensor 32d. When moisture is sensed by the moisture sensor 32d, the surface heat generator 32c can be controlled to generate heat.

The air blowing capacity of the air supply fan (43) is set such that the indoor air flowing into the first exhaust chamber (10) during the dew condensation control mode is discharged to the first exhaust chamber (30) The air blowing capacity of the air blower 25 can be set larger.

A filter 51 for filtering foreign substances contained in the air flowing into the total enthalpy heat exchanger 50 may be provided on one side of the total enthalpy heat exchanger 50 facing the first air feed chamber 30.

According to the ventilator of the present invention, the bypass passage, which can utilize the bypass flow path for indoor air for cooling the outside air, the flow path for cleaning indoor air, and the flow path for preventing condensation of the ventilation device, It is possible to effectively prevent condensation from occurring inside and outside of the ventilator and to sufficiently satisfy the necessary ventilation amount of the room occupancy, thereby creating a pleasant indoor environment.

Further, since the bypass passage is used as a flow path for passage of indoor air in the bypass mode, the air purifying mode and the condensation control mode, and a communication port communicating with the bypass passage is formed on the partition plate, Space can be ensured, thereby reducing the volume of the ventilation device and lowering the manufacturing cost.

In addition, in the air cleaning mode and the condensation control mode, since the indoor air flows via the bypass passage, compared to the case where only the conventional exhaust fan is driven or the preheater is used, the area where the condensation phenomenon of the ventilator is prevented It is possible to maximize the energy efficiency by preventing waste of energy at the same time.

If the temperature of the room air supplied from the second room to the room is lower than the dew point of the room-side air measured in the first room, or if the humidity of the room air discharged from the second room to the outside of the room exceeds the set humidity value , The mixing damper is opened and the number of revolutions of the air supply blower is automatically controlled so that the convenience of use of the ventilation device for preventing the occurrence of condensation can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic plan view (a) and a schematic side view (b) of a ventilator according to an embodiment of the present invention,
2 is a flow diagram of the ventilator shown in Fig. 1,
FIG. 3 is a control block diagram of the ventilator shown in FIG. 1;
4 is a schematic plan view (a) and a side schematic view (b) showing the heat exchange mode in the ventilator shown in Fig. 1,
FIG. 5 is a schematic view showing a heat exchange mode in the ventilator shown in FIG. 1;
6 is a schematic plan view (a) and a side schematic view (b) showing a bypass mode in the ventilator shown in Fig. 1,
FIG. 7 is a schematic view showing a bypass mode in the ventilator shown in FIG. 1;
8 is a schematic plan view (a) and a side schematic view (b) showing an air cleaning mode in the ventilator shown in Fig. 1,
FIG. 9 is a schematic diagram showing an air cleaning mode in the ventilator shown in FIG. 1;
Fig. 10 is a plan view (a) and a side schematic view (b) showing the dew condensation control mode in the ventilator shown in Fig. 1;
Fig. 11 is a flow diagram showing the dew condensation control mode in the ventilator shown in Fig. 1,
12 is a plan schematic view and (b) side schematic view of a ventilator according to another embodiment of the present invention,
Fig. 13 is a flow diagram of the ventilator shown in Fig. 12,
Fig. 14 is a control block diagram of the ventilator shown in Fig. 12; Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 3, a ventilator 1 according to an embodiment of the present invention includes a first exhaust chamber 10 through which indoor air flows, a second indoor chamber 10 through which indoor air A first air supply chamber 30 through which the outdoor air flows, a second air supply chamber 40 through which the outdoor air passed through the first air supply chamber 30 is supplied to the room, ) And the outdoor 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) And an total enthalpy heat exchanger (50). The ventilator 1 of the present invention is provided with the first exhaust chamber 10, the second exhaust chamber 20, the first exhaust chamber 30 And a bypass passage 70 is provided below the diaphragm 60. The diaphragm 60 is provided with a bypass passage 70,

In this embodiment, the bypass passage 70 is provided below the ventilator 1, but the bypass passage 70 may be provided above the ventilator 1.

Further, the ventilator (1) of the present invention has a heat exchange mode in which heat exchange is performed between indoor air to be exhausted and outdoor air to be supplied, a bypass mode in which outdoor air is supplied to the indoor side without heat exchange with indoor air, An air cleaning mode for recirculating indoor air to prevent condensation of the indoor air and condensation of the ventilating apparatus, and an outdoor air mode in which all or a part of the indoor air to be exhausted is mixed with outdoor air supplied to the indoor side, And a control unit 90 for controlling the operation of the ventilator 1 according to the mode set by the mode setting unit 80. The control unit 90 controls the operation of the ventilator 1 according to the mode set by the mode setting unit 80. [

In the bypass mode, the bypass passage 70 is formed in such a manner that the indoor air introduced into the first exhaust chamber 10 flows into the second exhaust chamber 20 side without passing through the total enthalpy heat exchanger 50, And in the case of the air clean mode, all of the room air introduced into the first exhaust chamber (10) flows to the first air supply chamber (30) side. In the case of the dew condensation control mode, All or a part of the room air introduced into the first exhaust chamber 10 is supplied to the first air supply chamber 30 so as to be mixed with the outdoor air flowing into the first air supply chamber 30.

An indoor air inlet (11) through which indoor air flows is provided on the indoor side of the first exhaust chamber (10). The first exhaust chamber 10 is provided with a first communication hole 10a formed in the partition plate 60 so as to communicate with the bypass passage 70 and an air cleaning damper 10a for opening and closing a passage through which indoor air flows to the total enthalpy heat exchanger 50 side. And a first temperature sensor 13 and a first humidity sensor 14 for measuring indoor temperature and humidity for calculating the dew point (dew point) of indoor air.

An indoor air discharge port (21) for discharging indoor air to an outdoor side is provided on an outdoor side of the second exhaust chamber (20). An indoor air discharge port An exhaust damper 23 is provided. The second exhaust chamber 20 is provided with a second communication hole 20a formed in the partition plate 60 so as to communicate with the bypass passage 70 and a bypass damper 22 for opening and closing the second communication hole 20a A second humidity sensor 24 for measuring the humidity of the indoor air exhausted from the second exhaust chamber 20 and an exhaust blower 25 for forcibly suctioning the indoor air to the outdoor side.

An outdoor air inlet 31 through which the outdoor air flows is provided at the outdoor side of the first air supply room 30. An air supply damper 33 for opening and closing a flow path through which outdoor air flows into the outdoor air inlet 31, . A third communication hole 30a formed in the partition plate 60 so as to communicate with the bypass passage 70 and a mixing damper 32 for opening and closing the third communication hole 30a are formed in the first chamber 30, Respectively.

1, the mixing damper 32 includes a rotation shaft 32a arranged to be orthogonal to a flow direction of room air passing through the third communication hole 30a, A damper plate 32b for opening and closing the third communication hole 30a, an area heating element 32c attached to the outdoor air introduction side surface of the damper plate 32b, And a moisture sensor 32d provided on the introduction side. When moisture is sensed by the moisture sensor 32d, the controller 90 controls the surface heat generator 32c to generate heat.

With this configuration, the room air in the relatively high temperature state flowing through the bypass passage 70 on the lower side of the third communication hole 30a on which the mixing damper 32 is installed, When moisture is generated in the damper plate 32b due to the condensation phenomenon caused by the temperature difference between the outdoor air at relatively low temperature flowing into the first chamber 30 and the outdoor air, The control unit 90 controls the power to be applied to the surface heating body 32c so that the surface of the damper plate 32b on the outdoor air introduction side is heated by the heat of the surface heating body 32c to heat the surface between the upper and lower surfaces of the damper plate 32b It is possible to prevent the occurrence of condensation.

The second air supply room 40 is provided with an outdoor air outlet 41 through which the outdoor air is discharged to the indoor side and the second air supply room 40 is provided with a second air supply outlet 41 for measuring the temperature of the outdoor air supplied to the room, A temperature sensor 42, and an air supply fan 43 for forcedly sucking outdoor air toward the indoor side.

The total enthalpy heat exchanger (50) has a structure in which a flow passage for flowing indoor air and a flow passage for flowing outdoor air are alternately formed and heat exchange is possible between the indoor air and the outdoor air. A filter (not shown) is disposed on one side of the total enthalpy heat exchanger (50) facing the first air supply chamber (30), for filtering out foreign air supplied from the outside air or indoor air recirculated in an air cleaning mode or a dew condensation control mode 51 are provided. The filter 51 may be a pre-filter, a medium filter, a HEPA filter, a deodorization filter, or the like.

Hereinafter, the operation of the heat exchange mode, the bypass mode, the air blindness mode, and the dew condensation control mode of the ventilator 1 according to the embodiment of the present invention will be described with reference to FIGS. 4 to 11. FIG.

4 and 5, in the heat exchange mode, the air filtering damper 12, the exhaust damper 23, and the air supply damper 33 are opened, and the bypass damper 22 and the mixing damper 32 are opened And the exhaust blower 25 and the air supply fan 43 are driven.

The indoor air flows into the first exhaust chamber 10 through the indoor air inlet 11 and then flows into the indoor air outlet 21 via the total enthalpy heat exchanger 50 and the second exhaust chamber 20, To the outdoor side. The outdoor air is introduced into the first air supply room 30 through the outdoor air inlet 31 and then discharged to the room side through the outdoor heat exchanger 50 and the second air supply room 40 through the outdoor air outlet 41 . The indoor air and the outdoor air pass through the total enthalpy heat exchanger (50) to perform heat exchange.

6 and 7, in the bypass mode, the bypass damper 22, the exhaust damper 23, and the air supply damper 33 are opened, and the air cleaning damper 12 and the mixing damper 32 are closed And the exhaust blower 25 and the air supply fan 43 are driven.

Accordingly, in the bypass mode, the indoor air flows into the first exhaust chamber 10 through the indoor air inlet 11 and then flows downward through the first communication hole 10a, The indoor air passing through the bypass passage 70 is flowed upward through the second communication port 20a and flows into the second exhaust chamber 20, And is discharged to the outdoor side through the discharge port (21). The outdoor air is introduced into the first air supply room 30 through the outdoor air inlet 31 and then discharged to the room side through the outdoor heat exchanger 50 and the second air supply room 40 through the outdoor air outlet 41 .

Therefore, in the bypass mode, heat exchange is not performed between the exhausted indoor air and the outdoor air to be supplied, and the outdoor air is supplied to the indoor side without changing the temperature.

6 (a), the dashed arrows indicate the flow paths of the room air passing through the bypass passage 70, and the relatively thick lines in FIG. 7 show the flow paths of the room air and the room air, This is the same in the following drawings.

8 and 9, in the air cleaning mode, the mixing damper 32 is opened and the air cleaning damper 12, the bypass damper 22, the exhaust damper 23, and the air supply damper 33 are closed And the air supply fan 43 is driven.

Therefore, in the recirculation mode, the room air is introduced into the first exhaust chamber 10 through the room air inlet 11, and then the flow direction is switched downward through the first communication hole 10a, The indoor air passed through the bypass passage 70 is flowed upward through the third communication hole 30a and flows into the first air supply chamber 30, 50 and the second class air chamber 40 and is discharged to the room side.

In this air clean mode, the foreign substances contained in the recirculated indoor air are filtered by the filter 51, so that the indoor air can be cleaned and the indoor air can be circulated through the bypass passage 70 It is possible to prevent the occurrence of condensation in the entire area of the ventilator 1 and to prevent the occurrence of condensation in the bypass passage 70 It is possible to prevent the propagation of bacteria due to the air pollution which may be caused when the air flow stagnates inside the inside of the indoor space.

10 and 11, in the dew condensation control mode, the air cleaning damper 12, the exhaust damper 23, the mixing damper 32 and the air supply damper 33 are opened and the bypass damper 22 is closed And the exhaust blower 25 and the air supply fan 43 are driven.

Therefore, in the condensation control mode, a part of the room air introduced into the first exhaust chamber 10 through the room air inlet 11 is changed in flow direction downward through the first communication hole 10a, The indoor air passing through the bypass passage 70 is flowed upward through the third communication port 30a to flow into the first air supply chamber 30, Is mixed with the outdoor air introduced into the air supply chamber 30 and is exhausted to the room side through the total enthalpy heat exchanger 50 and the second air supply room 40 and flows into the first exhaust chamber 10 through the room air inlet 11 The rest of the introduced indoor air passes through the total enthalpy heat exchanger (50) and the second exhaust chamber (20) and is exhausted to the outside. In the condensation control mode, all of the room air introduced into the first exhaust chamber 10 through the room air inlet 11 flows through the first communication hole 10a, the bypass passage 70 and the third communication hole 30a to flow into the first air supply chamber 30. In this case, the air cleaning damper 12 can be controlled to be closed.

In the condensation control mode, it is possible to introduce fresh outdoor air to the indoor side together with the recirculation of the indoor air, thereby satisfying the necessary ventilation amount of the indoor resident room, thereby creating a pleasant indoor environment and preventing generation of sound pressure in the indoor space So that it is possible to prevent the inflow of the contaminated and cold outdoor air which may be caused when the sound pressure is generated. Also, in the condensation control mode, as in the case of the above-described air cleaning mode, room air flows into the bypass passage 70 formed over the entire lower portion of the ventilator 1, And it is possible to prevent the propagation of bacteria caused by the air pollution which may be caused when the air flow is stagnated inside the bypass passage 70.

On the other hand, the control unit 90 controls the dew point of the indoor air calculated by the temperature and humidity values measured by the first temperature sensor 13 and the second humidity sensor 14, When the temperature measured by the second temperature sensor 42 is lower than the dew point of the room-side air, the mixing damper 32 is opened, and when the temperature measured by the second temperature sensor 42 is lower than the dew point of the indoor air, The number of revolutions of the condenser 43 is increased so as to prevent condensation.

When the humidity of the indoor air measured by the second humidity sensor 24 exceeds the set humidity value (for example, relative humidity 80 to 90%), the controller 90 controls the mixing damper 32 Is opened and the number of revolutions of the air supply fan (43) is increased, thereby preventing the occurrence of condensation.

The ventilator 1 according to another embodiment of the present invention shown in FIG. 12 to FIG. 14 includes the first temperature sensor 13 and the first humidity sensor 14, which are the configurations of the above- (15), and other configurations are the same as those of the above-described embodiment.

In the present embodiment, the controller 90 compares the temperature of the indoor air measured by the dew point temperature sensor 15 with the temperature of the outdoor air supplied to the room measured by the second temperature sensor 42, When the temperature measured by the temperature sensor 42 is lower than the dew point of the indoor air measured by the dew point temperature sensor 15, the mixing damper 32 is opened and the rotation speed of the air supply fan 43 So that the occurrence of condensation is prevented.

The air blowing capacity of the air supply blower 43 is set such that the room air flowing into the first exhaust chamber 10 in the dew condensation control mode corresponds to the set flow rate bypassed to the first air supply chamber 30 Is set to be larger than the blowing capacity of the exhaust blower (25).

For example, when the flow rate of the air exhausted through the outdoor air outlet 21 is 100, the flow rate of the air supplied through the outdoor air inlet 31 is 100, the flow rate of the room air mixed into the outdoor air to be supplied is 50 The indoor air of the flow rate 150 flows into the room air inlet 11 and the flow rate 100 of the room air of the flow rate 150 flows through the total enthalpy heat exchanger 50 and the exhaust blower 25 of the second exhaust chamber 20 The flow rate 50 of the room air having a flow rate of 150 flows into the first feed chamber 30 via the bypass passage 70 and then flows into the first feed chamber 30 through the outdoor air inlet 31, The air having the flow rate 150 mixed in the first air supply chamber 30 is mixed with the outdoor air having the flow rate of 100 introduced into the indoor heat exchanger 50 through the air supply fan 43 of the second air supply chamber 40 .

In this case, the exhaust blower 25 is set to a capacity capable of blowing air having a flow rate of 100, and the air supply fan 43 is set to a capacity capable of blowing air having a flow rate of 150.

According to the ventilator 1 of the present invention configured as described above, it is possible to use both the bypass mode and the air purifying mode and the condensation control mode as a flow path for passage of room air in the lower or upper part of the ventilator 1 And by controlling the ventilator 1 to operate in accordance with the condition for each mode, it is possible to effectively prevent the occurrence of condensation in the entire area of the ventilator and to reduce the required ventilation amount of the occupant in the room There is an advantage that energy efficiency can be maximized while satisfying sufficiently.

1: Ventilation device 10: First exhaust chamber
10a: first communicating port 11: indoor air inlet
12: air cleaner damper 13: first temperature sensor
14: first humidity sensor 15: dew point temperature sensor
20: second exhaust chamber 20a: second communication hole
21: Indoor air outlet 22: Bypass damper
23: exhaust damper 24: second humidity sensor
25: exhaust blower 30: first class room
30a: third communication port 31: outdoor air inlet
32: mixing damper 32a:
32b: damper plate 32c: planar heating element
32d: moisture sensor 33: supply damper
40: second class room 41: outdoor air outlet
42: second temperature sensor 43: air supply blower
50: total heat exchanger 51: filter
60: diaphragm 70: bypass passage
80: Mode setting section 90:

Claims (10)

A first exhaust chamber 10 through which indoor air flows, a second exhaust chamber 20 through which indoor air passed through the first exhaust chamber 10 is discharged to the outside, a first exhaust chamber 30 through which outdoor air flows, A second air supply chamber 40 for supplying outdoor air via the first air supply chamber 30 to the room and a second air supply chamber 40 for supplying indoor air flowing into the second exhaust chamber 20 from the first exhaust chamber 10, And an outdoor heat exchanger (50) in which heat exchange is performed between outdoor air flowing from the first air supply room (30) to the second air supply room (40)
A diaphragm 60 is disposed on one side of the first exhaust chamber 10, the second exhaust chamber 20, the first feed chamber 30, the second feed chamber 40, and the total enthalpy heat exchanger 50, A pass passage 70 is formed,
The bypass passage (70)
In the bypass mode, the indoor air introduced into the first exhaust chamber (10) flows to the second exhaust chamber (20) side without passing through the total enthalpy heat exchanger (50)
In the air clean mode, all of the room air introduced into the first exhaust chamber (10) provides a flow path to the first air supply chamber (30) side,
In the condensation control mode, all or a part of the room air introduced into the first exhaust chamber (10) is mixed with the outdoor air to be supplied to the first air supply room (30) to the first air supply room And a flow path is provided.
The method according to claim 1,
The first exhaust chamber 10 is provided with a first communication hole 10a formed in the partition plate 60 so as to communicate with the bypass passage 70 and a passage through which the room air flows toward the total enthalpy heat exchanger 50 An air cleaning damper 12 for opening and closing is provided,
The second exhaust chamber 20 is provided with a second communication hole 20a formed in the partition plate 60 so as to communicate with the bypass passage 70 and a bypass damper 20a which opens and closes the second communication hole 20a. And an exhaust damper (23) for opening and closing a passage through which indoor air introduced into the second exhaust chamber (20) is exhausted to the outside,
A third communication hole 30a formed in the partition plate 60 so as to communicate with the bypass passage 70 and a mixing damper 30a opening and closing the third communication hole 30a are formed in the first feed chamber 30, 32), and an air supply damper (33) for opening and closing a passage through which outdoor air flows into the first air supply room (30).
3. The method of claim 2,
In the air cleaning mode,
The mixing damper 32 is opened and the air cleaning damper 12, the bypass damper 22, the exhaust damper 23 and the air supply damper 33 are closed and the air supply fan 43 is driven Characterized by a ventilation device.
3. The method of claim 2,
In the condensation control mode,
The air damper 12, the exhaust damper 23, the mixing damper 32 and the air supply damper 33 are opened and the bypass damper 22 is closed and the air blowing fan 25, (43) is driven.
3. The method of claim 2,
The first exhaust chamber (10) is provided with a first temperature sensor (13) and a second humidity sensor (14) for measuring the dew point of indoor air,
The second air supply room (40) is provided with a second temperature sensor (42) for measuring the temperature of outdoor air supplied to the room,
When the temperature measured by the second temperature sensor 42 is lower than the dew point of the indoor air, the mixing damper 32 is opened and the number of revolutions of the air supply fan 43 is controlled to be increased Ventilation system.
3. The method of claim 2,
The first exhaust chamber (10) is provided with a dew point temperature sensor (15) for measuring the dew point of indoor air,
The second air supply room (40) is provided with a second temperature sensor (42) for measuring the temperature of outdoor air supplied to the room,
When the temperature measured by the second temperature sensor 42 is lower than the dew point of the indoor air, the mixing damper 32 is opened and the number of revolutions of the air supply fan 43 is controlled to be increased Ventilation system.
3. The method of claim 2,
The second exhaust chamber (20) is provided with a second humidity sensor (24) for measuring the humidity of indoor air to be exhausted,
When the humidity measured by the second humidity sensor (24) exceeds a predetermined humidity value, the mixing damper (32) is opened and the number of revolutions of the air supply fan (43) is controlled to be increased Device.
3. The method of claim 2,
The mixing damper 32 includes a rotation shaft 32a arranged so as to be orthogonal to a flow direction of the room air passing through the third communication hole 30a and a second communication hole 32b which is rotated about the rotation axis 32a, A damper plate 32b that opens and closes the damper plate 32b and a surface heat emission element 32c attached to the outdoor air introduction side surface of the damper plate 32b, And a moisture sensor 32d,
And the surface heat emission element (32c) is controlled to generate heat when moisture is sensed by the moisture sensor (32d).
5. The method of claim 4,
The air blowing capacity of the air supply fan (43) is set such that the indoor air flowing into the first exhaust chamber (10) during the dew condensation control mode is discharged to the first exhaust chamber (30) Is set larger than the ventilation capacity of the blower (25).
The method according to claim 1,
And a filter 51 for filtering foreign substances contained in the air flowing into the total enthalpy heat exchanger 50 is provided on one side of the total enthalpy heat exchanger 50 facing the first air feed chamber 30 Ventilation system.

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