KR100850942B1 - ventilating device and method of operating the same - Google Patents

Abstract

The present invention relates to a ventilation device and a method of operating the same, which can minimize energy loss while ensuring ventilation efficiency. To this end, the operating method of the ventilator according to the present invention is a temperature detection step (S11) that the indoor temperature sensor detects the room temperature (T _IN ) and the outdoor temperature sensor detects the outdoor temperature (T _OUT ) and the controller In the temperature difference detection step (S13) for detecting the indoor and outdoor temperature difference detected by the temperature sensor, and when the temperature difference is less than a predetermined value as a result of the temperature difference detection, the controller opens the rapid exhaust duct 30 to the indoor air heat exchanger (5). Heat exhaust ventilation step (S15) is immediately discharged to the outdoor without passing through) and, if the temperature difference detection result temperature difference is more than a predetermined value, the controller closes the rapid exhaust duct and the indoor air is discharged to the outdoor through the total heat exchanger It is comprised including S17. At this time, the heat exchange ventilation step is a temperature comparison step (S19, S21) in which the controller compares the outdoor temperature (T _OUT ) with a preset reference temperature, and the air supply fan 15 and the exhaust fan 25 in accordance with the result of the temperature comparison The air volume of the air volume control step (S23, S25) is further included.

Ventilation device, operation method

Description

Ventilating device and method of operating the same

1 is a schematic view showing the structure of a general electrothermal exchange ventilator

Figure 2 is a block diagram showing the main configuration of the total heat exchange ventilation system according to the present invention

Figure 3 is a schematic diagram showing the structure of the total heat exchange ventilation system according to the present invention

Figure 4 is a flow chart showing the operation of the total heat exchange ventilation system according to the present invention

5a and 5b is a configuration diagram showing an operating state of the total heat exchange type ventilator according to the present invention, respectively

Explanation of symbols on the main parts of the drawings

1 case 5 heat exchanger

10: supply duct 15: supply fan

20: exhaust duct 25: exhaust fan

30: rapid exhaust duct 40: exhaust damper

The present invention relates to an electrothermal exchange ventilator and its operation method, and more particularly, by reducing the amount of outdoor air supplied and the amount of indoor air exhausted according to the temperature difference between indoor and outdoor, thereby minimizing energy loss while ensuring ventilation efficiency. And a method for optimally operating the ventilation device.

The air in an enclosed space increases the carbon dioxide content over time due to the breathing of living things, which interferes with the breathing of living things. Therefore, if many people stay in a narrow space such as an office or a vehicle, it is necessary to frequently replace the indoor air with fresh air. At this time, a commonly used ventilation device.

Most conventional ventilation apparatuses employ a method of forcibly discharging only indoor air to the outside using a single blower. However, if only one air is forced out by using one blower, the indoor cold air or heat is discharged to the outside without filtration, and the outdoor air is heated without heat exchange through a door or window gap. The cost of cooling was unnecessarily high.

In addition, due to the sudden inflow of cold air and heat from inside to outside people suddenly change the temperature of the interior people there is unpleasant feelings, especially in the state that the indoor window or door frame closed to discharge only the indoor air to the outside In this case, the inflow of fresh air can be blocked and oxygen deficiency can occur, and the humidity of the indoor air is not controlled at all. there was.

In order to solve this problem, a total heat exchange type ventilation device for first exchanging outdoor air with indoor air discharged to the outside and then supplying the indoor air has been proposed.

Figure 1 schematically shows the structure of a general electrothermal exchange ventilator.

As shown in FIG. 1, an air supply duct 10 is provided inside a box-shaped case 1 to guide outdoor air to an interior, and the air duct intersects with the air supply duct at a predetermined position, and the air is guided to the outside. Duct 20 is provided. In addition, an electric heat exchanger (5) is provided to exchange heat between the outdoor air that is supplied at the point where the air supply duct 10 and the exhaust duct 20 intersect and the indoor air that is exhausted.

An air supply inlet 11 is formed at one end of the air supply duct 10 to communicate with the outside, and an air supply outlet 13 is formed to communicate with the room at the other end thereof, and an air exhausted to communicate with the room at one end of the exhaust duct 20. An intake port 21 is formed and an exhaust outlet 23 is formed at the other end in communication with the outdoors.

At this time, the air supply duct 10 and the exhaust duct 20 do not interfere with each other while crossing the inner space of the case 1 up and down with respect to the heat exchanger, respectively. The air supply duct 10 is formed by the partition wall 10a extending to the air supply inlet port 11 around the heat exchanger 5 and the partition wall 10b extending to the air supply outlet port 13. 20 is also possible because it is formed by the partition 20a extending to the exhaust inlet 21 and the partition 20b extending to the exhaust outlet 23 around the total heat exchanger.

An air supply fan 15 for forcibly sucking outdoor air is provided on the air supply outlet side of the air supply duct 10, and an exhaust fan 25 for forcibly discharging indoor air is provided on the air outlet side of the exhaust duct 20. do.

Meanwhile, the heat exchanger 5 has a hexahedron shape in which upper and lower edges are supported by the case 1 and left and right edges are supported by a plurality of partition walls that divide the air supply duct 10 and the exhaust duct 20. A plurality of air supply passages 5a communicating with the air supply duct 10 and a plurality of air exhaust passages 5b adjacent to the air supply passages and communicating with the exhaust duct 20 are provided. Although not shown, a heat exchange membrane having excellent heat conduction efficiency is provided at the boundary between the air supply passage 5a and the exhaust passage 5b.

At this time, the part shown on the right side in the drawing is the air supply passage 5a, and the part shown on the left side is the exhaust passage 5b.

Referring to the operation of the electrothermal exchange system ventilator configured as described above are as follows.

First, when indoor air is contaminated to some extent, power is supplied to the exhaust fan 25, and indoor air flows into the exhaust duct 20 through the exhaust inlet 21, and then passes through the exhaust passage 5b of the total heat exchanger. It is discharged to the outside through the exhaust outlet 23.

At the same time, while supplying power to the air supply fan 15, fresh outdoor air flows into the air supply duct 10 through the air supply inlet 11, and then passes through the air supply passage 5a of the heat exchanger, and supplies the air supply outlet 13. Through the room.                         

At this time, the indoor air and the outdoor air passing through the heat exchanger (5) exchange heat through the heat exchange membrane. Specifically, the heat exchange occurring in the total heat exchanger 5 includes sensible heat exchange occurring between the outdoor air to be supplied and the indoor air to be exhausted, and the hot air of the indoor or outdoor air is dew point temp. It becomes the latent heat exchange by the condensate produced | generated while being in the following states.

As described above, in the case of an electrothermal exchange type ventilator, outdoor air that is supplied when the room is cooled or heated is primarily heat-exchanged with the indoor air and then introduced into the room, thereby preventing a sudden rise or fall of the room temperature. Can be.

However, as described above, the ventilator as described above always introduces a certain amount of outdoor air regardless of the temperature difference between the inside and the outside of the ventilator to ventilate the room, thereby causing a problem of consuming more energy than necessary. That is, the temperature of the outdoor air introduced into the room through the heat exchanger (5) generally has a median value between the room temperature and the outdoor temperature. Even if the heat exchanges with the indoor air through the exchanger, the temperature can be significantly different from the indoor temperature. Therefore, in order to keep the indoor environment more comfortable, the air conditioner or the heater must be continuously operated to maintain a constant room temperature, in which case the energy required is inevitably a loss due to ventilation.

On the contrary, when the indoor and outdoor temperature difference is small, it is always a certain amount of outdoor air is introduced through the heat exchanger (5) to ventilate the room, rather it will have an adverse effect on the ventilation efficiency. That is, when the temperature difference between the indoor and outdoor is small, the temperature of the outdoor air is not significantly different from the indoor temperature. Therefore, it is desirable to focus on ventilating the room by introducing a larger amount of outdoor air into the room rather than heat exchange efficiency. However, conventionally, despite the small temperature difference between indoor and outdoor, the ventilation efficiency is lowered by always ventilating the room using a certain amount of outdoor air.

The present invention has been made to solve the above problems, an object of the present invention is to reduce the energy loss while ensuring ventilation efficiency by adding or subtracting the amount of outdoor air and the amount of indoor air exhausted according to the temperature difference between the indoor and outdoor. To provide ventilation.

Another object of the present invention is to provide a method of operating a ventilator capable of automatically operating the ventilator so as to ensure ventilation efficiency while minimizing energy loss.

In order to achieve the above object, a ventilator according to the present invention is a plurality of air supply passage communicating with the air supply duct and a plurality of exhaust passage communicating with the exhaust duct are formed so as to be adjacent to each other and the heat exchanger and the heat exchange between the air supply and the exhaust, An air supply fan and an exhaust fan which are respectively provided in the air supply duct and the air exhaust duct, the rapid exhaust duct branched from the exhaust duct so that indoor air can be rapidly discharged to the outside without passing through the heat exchanger, and the exhaust air An exhaust damper provided at a branch point of the duct and the rapid exhaust duct to selectively open the rapid exhaust duct, an indoor temperature sensor for detecting an indoor temperature, an outdoor temperature sensor for detecting an outdoor temperature, and a temperature sensor detected by the temperature sensor Control the opening and closing of the exhaust damper and controlling the air volume of the supply fan and the exhaust fan according to the temperature difference between indoor and outdoor using the temperature It comprises a roller.

The operating method of the ventilation apparatus according to the present invention includes a temperature detecting step of detecting an indoor temperature by an indoor temperature sensor and an outdoor temperature by an outdoor temperature sensor, and a temperature difference of detecting an indoor / outdoor temperature difference detected by the temperature sensor by a controller. The detecting step, and if the temperature difference is less than a predetermined value as a result of the temperature difference detection, the controller opens the rapid exhaust duct to quickly discharge the indoor air to the outside without passing through the heat exchanger, and the temperature difference resulted in the temperature difference is more than a predetermined value In this case, the controller is configured to include a heat exchange ventilation step of closing the rapid exhaust duct so that indoor air is discharged to the outside through the total heat exchanger.

At this time, the heat exchange ventilating step further includes a temperature comparison step in which the controller compares the outdoor temperature with a preset reference temperature, and a flow rate adjusting step in which air flow rates of the air supply fan and the exhaust fan are differently operated according to the result of the temperature comparison.

Therefore, the ventilator and the method of operating the same according to the present invention control the operating speed of the air supply fan and the exhaust fan while controlling the flow rate of the indoor air exhausted according to the temperature difference between the indoor and outdoor, and the indoor air exhausted and the indoor air exhausted. By reducing the amount of air, it provides the advantage of minimizing the energy loss by preserving the indoor atmosphere as much as possible while providing improved ventilation efficiency.

Hereinafter, with reference to the accompanying drawings, the ventilation apparatus and its operation method according to a preferred embodiment of the present invention in more detail.

First, Figure 2 is a block diagram showing the main configuration of the total heat exchange ventilator according to the present invention, Figure 3 is a schematic diagram showing the structure of the total heat exchange ventilator according to the present invention.

As shown in FIG. 2, the ventilator according to the present invention includes a controller for controlling the overall operation of the system, an indoor temperature sensor and an outdoor temperature sensor for detecting indoor and outdoor temperatures, respectively, and operating by the controller. It is configured to include an air supply fan and an exhaust fan to control the air volume by controlling the speed differently, and an exhaust damper for adjusting the flow path of the indoor air to be exhausted.

The indoor temperature sensor and the outdoor temperature sensor detect an indoor temperature and an outdoor temperature, respectively, and apply them as electrical signals to the controller, and the controller uses a signal applied from a temperature sensor to determine a difference between the indoor temperature and the outdoor temperature. Compute or compare the outdoor temperature with a plurality of preset reference temperature.

The controller controls opening / closing of the exhaust air damper by controlling the opening and closing of the exhaust damper according to a previously input program when the temperature difference between the inside and the outside is less than a predetermined value based on the above-described calculation process. In addition, the controller controls the operating speed by controlling the power applied to the air supply fan and the exhaust fan according to the range of the outdoor temperature, thereby adjusting the amount of outdoor air supplied and the amount of indoor air exhausted.

Hereinafter, the structure of the above-described ventilation device in more detail as follows.                     

As shown in FIG. 3, the ventilation device according to the present invention has an air supply duct 10 in which outdoor air is guided to the inside of a box-shaped case 1, and the air supply duct intersects at a predetermined position. Including the exhaust duct 20 to be guided to the outside, and the heat exchanger (5) is provided at the intersection of the air supply duct 10 and the exhaust duct 20, the heat exchanged outdoor air and the indoor air exhausted It is composed.

An air supply inlet 11 and an air supply outlet 13 are formed at one end and the other end of the air supply duct 10, respectively, and an exhaust inlet 21 and an exhaust outlet 23 are also provided at one end and the other end of the exhaust duct 20, respectively. Is formed.

At this time, the air supply duct 10 and the exhaust duct 20 do not interfere with each other while crossing the inner space of the case 1 up and down with respect to the heat exchanger, respectively. The air supply duct 10 is formed by a partition wall 10a extending to the air supply inlet port 11 and a partition wall 10b extending to the air supply outlet port 13, and the exhaust duct 20 also extends. This is possible because it is formed by the partition wall 20a extending to the exhaust inlet port 21 and the partition wall 20b extending to the exhaust port port 23 around the heat exchanger.

The ventilator includes a rapid exhaust duct 30 branched from the exhaust duct 20 so that indoor air can be directly discharged to the outdoors without passing through the heat exchanger 5. To this end, the rapid exhaust duct 30 is provided between the upper end of the total heat exchanger (5) and the case (1) and communicate with the exhaust inlet (21) and the exhaust outlet (23).

Since the rapid exhaust duct 30 should be opened only when the temperature difference between indoor and outdoor is very small, an exhaust damper 40 selectively opening the rapid exhaust duct at the branch point of the exhaust duct 20 and the rapid exhaust duct is provided. It is provided. At this time, the exhaust damper 40 is preferably provided in front of the heat exchanger (5) based on the exhaust direction of the indoor air.

In order to perform the above-described role, the exhaust damper 40 includes a plate member 42 for selectively opening the quick exhaust duct 30 while rotating about a hinge provided at one edge of the total heat exchanger 5. do. At this time, the operation of the plate member 42 may be implemented by a variety of driving means, for example, a cylinder for receiving hydraulic pressure and a piston for pushing and pulling the plate member while linearly reciprocating by the hydraulic pressure of the cylinder ( 44), and both ends are connected to one side of the piston and the plate-like member to propose a means consisting of an operating lever 43 for transmitting the movement of the piston to the plate-like member 42.

An air supply fan 15 for forcibly sucking outdoor air is provided on the air supply outlet side of the air supply duct 10, and an exhaust fan 25 for forcibly discharging indoor air is provided on the air outlet side of the exhaust duct 20. do. At this time, the air supply fan 15 and the exhaust fan 25 should be capable of adjusting the air volume as described above.

On the other hand, the heat exchanger (5) has a hexahedral shape in which the bottom edge is supported by the case (1) and the left and right edges are supported by a plurality of partition walls partitioning the air supply duct (10) and the exhaust duct (20). A plurality of air supply passages 5a communicating with the air supply duct 10 and a plurality of air exhaust passages 5b adjacent to the air supply passages and communicating with the exhaust duct 20 are provided. Although not shown, a heat exchange membrane having excellent heat conduction efficiency is provided at the boundary between the air supply passage 5a and the exhaust passage 5b.

At this time, the portion shown on the right side of the drawing is the air supply passage 5a, and the portion shown on the left side is the exhaust passage 5b.

Meanwhile, although the controller, the indoor side temperature sensor, and the outdoor side temperature sensor are not shown in FIG. 3, the controller has an exhaust damper 40 and an air supply fan 15 on one side of the case 1 to perform the above-described function. And it is provided to control the exhaust fan 25, the indoor temperature sensor and the outdoor temperature sensor is provided to apply an electrical signal to the controller in the indoor and outdoor, respectively. Even if these specific connections are not explained, those of ordinary skill in the art can fully understand them.

Hereinafter, the operation method of the ventilation device as described above in more detail.

First, Figure 4 is a flow chart showing the operation of the total heat exchange ventilation system according to the present invention, Figures 5a and 5b is a configuration diagram showing the operating state of the total heat exchange ventilation system according to the present invention, respectively.

As shown in FIG. 4, in the operating method of the ventilation apparatus according to the present invention, a temperature detection step in which an indoor temperature sensor detects an indoor temperature and an outdoor temperature sensor detects an outdoor temperature is performed (S11). At this time, the indoor temperature and the outdoor temperature are input to the controller as an electrical signal.

Next, the temperature difference detection step of calculating the indoor and outdoor temperature difference detected by the indoor temperature sensor and the outdoor temperature sensor in the controller is performed (S13). At this time, the controller calculates the difference between the input indoor temperature T _IN and the outdoor temperature T _OUT as an absolute value.

Next, when the absolute difference between the indoor and outdoor temperature difference is less than 5 in the temperature difference detecting step (S13), the rapid exhaust duct is opened to rapidly discharge the indoor air to the outdoor without passing through the heat exchanger (S15). do. The rapid evacuation step is well illustrated in FIG. 5A.

As shown in FIG. 5A, the controller adjusts the hydraulic pressure supplied to the cylinder 45 to push the piston 44 out of the cylinder so that the plate-shaped member 42 is half the hinge about the extended length of the piston. It rotates in a clockwise direction so that one end thereof is in contact with the partition wall 20a of the exhaust duct, and eventually the exhaust flow path to the total heat exchanger 5 is blocked.

Therefore, the indoor air flows into the exhaust duct 20 through the exhaust inlet 21 while the power is applied to the exhaust fan 25, and then the exhaust damper 40 is directed to the exhaust heat exchanger 5. Blocking is directed to the rapid exhaust duct (30). After that, the indoor air is completely discharged to the outside through the exhaust outlet 23. Therefore, the indoor air can be rapidly discharged to the outside without passing through the heat exchanger (5).

On the other hand, it is preferable that power is also applied to the air supply fan 15 to replenish the outdoor air as much as the exhausted indoor air. In this case, the outdoor air is introduced into the air supply duct 10 through the air supply air inlet 11 by the operation of the air supply fan, and then is introduced into the room through the air supply outlet 5a through the air supply passage 5a of the heat exchanger. .

As described above, the rapid exhaust stage (S15) according to the present invention provides an advantage that the indoor air can be ventilated more quickly while preserving the indoor temperature as much as possible when the temperature difference between the indoor and outdoor is very small. That is, even if the outdoor air does not heat exchange with the indoor air, the indoor air can be preserved as the outdoor air flows into the room with the same temperature as the indoor temperature, and the rapid exhaust duct 30 without contaminant outdoor air is prevented. Through faster discharge to the outdoor can improve the ventilation efficiency.

Next, when the absolute difference between the indoor and outdoor temperature difference is 5 or more in the temperature difference detection step (S13), the heat exchange ventilation step is performed in which the outdoor air that is supplied by closing the rapid exhaust duct 30 exchanges heat with indoor air (S17). ). The heat exchange ventilating step is well illustrated in FIG. 5B.

As shown in FIG. 5B, the controller adjusts the hydraulic pressure supplied to the cylinder 45 to pull the piston 44 into the cylinder, so that the plate-shaped member 42 watches around the hinge by the reduced length of the piston. Direction is rotated in one end thereof is in contact with the case 1, and eventually the exhaust flow path to the rapid exhaust duct 30 is blocked.

Therefore, the indoor air flows into the exhaust duct 20 through the exhaust inlet 21 as the power is applied to the exhaust fan 25, and then passes the exhaust outlet 23 through the exhaust passage 5b of the total heat exchanger. Is discharged to the outdoors. At the same time, power is also applied to the air supply fan 15 so that outdoor air flows into the air supply duct 10 through the air supply inlet 11, and then passes through the air supply passage 5a of the heat exchanger and passes the air supply outlet 13. Through the room.

At this time, the indoor air and the outdoor air passing through the heat exchanger 5 exchange heat through the heat exchange membrane while passing through the exhaust passage 5b and the air supply passage 5a, respectively, and thus the outdoor air has a temperature close to the room temperature. It flows into the room.                     

On the other hand, the heat exchange ventilating step (S17) further includes a flow rate adjusting step (S23, S25) in which the air volume of the air supply fan 15 and the exhaust fan 25 is operated differently according to the outdoor temperature (T _OUT ).

To this end, a plurality of reference temperatures are preset in the controller, and the controller performs an operation of comparing the outdoor temperature T _OUT input from the outdoor temperature sensor with the reference temperature (S19, S21), According to the comparison result, the power supplied to the air supply fan 15 and the exhaust fan 25 is adjusted to control the air volume of the air supply fan and the exhaust fan in two stages.

At this time, when the appropriate room temperature is about 30 ° C, the reference temperature is preferably in the range of about ± 10 ° C or more than the proper room temperature. This is because the temperature of the outdoor air supplied through the total heat exchanger 5 has an intermediate value between the room temperature and the outdoor temperature. The difference is only about ℃, because the energy loss caused by the difference is enough to afford to ventilate the room.

In detail, when the upper limit value is 40 ° C. and the lower limit value is 20 ° C. as the reference temperature, when the outdoor temperature T _OUT is higher than 40 ° C., the air supply fan 15 and the exhaust fan 25 are operated with light wind. In operation S23, when the outdoor temperature is 40 ° C. or less, the air supply fan and the exhaust fan are driven in a strong wind (S25). In addition, when the outdoor temperature T _OUT is lower than 20 ° C., the air supply fan 15 and the exhaust fan 25 are driven with weak wind (S23), and when the outdoor temperature is 20 ° C. or higher, the air supply fan and the exhaust fan are operated with a strong wind. (S25).

At this time, the operation of the air supply fan 15 and the exhaust fan 25 in the mild wind and strong wind can be achieved by adjusting the rotational speed according to the applied power controlled by the controller.

The step S23 of driving the air supply fan and the exhaust fan in a mild wind is a heat exchange ventilation step of minimizing energy loss by preserving the room temperature to the maximum rather than the ventilation efficiency. That is, when the outdoor temperature T _OUT is higher than 40 ° C. or lower than 20 ° C., there is a significant difference between the outdoor temperature and the appropriate indoor temperature. In this case, the air supply fan 15 and the exhaust fan 25 are operated at a low speed. By minimizing the amount of outdoor air to be supplied and the amount of indoor air to be exhausted, it is possible to achieve maximum degree of ventilation while preserving a certain degree of ventilation.

On the contrary, the step (S25) of driving the air supply fan and the exhaust fan in a strong wind is a heat exchange ventilation step that can improve ventilation efficiency rather than minimizing energy loss. That is, when the outdoor temperature (T _OUT ) is 20 ℃ or more and 40 ℃ or less, there is no difference between the outdoor temperature and the appropriate indoor temperature. In this case, the air supply fan 15 and the exhaust fan 25 are operated at high speed to supply air. By maximizing the amount of outdoor air and the amount of indoor air exhausted, it is possible to improve the ventilation efficiency while preserving the indoor temperature to some extent.

As described above, the heat exchanging ventilation step can develop its performance under seasonal conditions where the four seasons are distinct and the temperature difference between the indoor and outdoor is not constant. That is, in summer and winter when the temperature difference between indoor and outdoor is extreme, the heat exchange ventilation step (S23), which mainly operates the air supply fan and the exhaust fan in a mild wind, is applied to prevent energy loss.In contrast, in the spring and autumn season, the air supply fan and the exhaust fan are prevented. Heat exchange ventilation step (S25) of driving in a strong wind can be applied to ensure the maximum ventilation efficiency.                     

So far, the present invention has been described with reference to preferred embodiments thereof, and one of ordinary skill in the art to which the present invention pertains may implement the modified embodiment within the essential technical scope of the present invention. Here, the essential technical scope of the present invention is shown in the claims, and the modified forms within the equivalent range will be construed as being included in the present invention.

Ventilation apparatus and its operation method according to the present invention provides the following effects.

First, according to the present invention, when the temperature difference between the indoor and outdoor is very small, the exhausted indoor air is discharged directly to the outdoor without passing through the heat exchanger, thereby providing the advantage of allowing the air to be ventilated more quickly while preserving the indoor temperature as much as possible. do.

Second, according to the present invention by varying the amount of outdoor air supplied and the amount of indoor air exhausted according to the outdoor temperature, it provides an advantage of preventing energy loss by preserving the indoor atmosphere to the maximum while improving the ventilation efficiency.

Claims (7)

A total heat exchanger in which a plurality of air supply passages communicating with the air supply duct and a plurality of air exhaust passages communicating with the exhaust duct are formed adjacent to each other so that the air supply and the exhaust heat exchange; An air supply fan and an exhaust fan provided in the air supply duct and the air exhaust duct, respectively, to control the air volume; A rapid exhaust duct branched from the exhaust duct so that indoor air can be rapidly discharged to the outside without passing through the heat exchanger; An exhaust damper provided at a branch point of the exhaust duct and the rapid exhaust duct and selectively opening the rapid exhaust duct; An indoor temperature sensor detecting an indoor temperature and an outdoor temperature sensor detecting an outdoor temperature; And a controller configured to control the opening and closing of the exhaust damper and the air volume of the air supply fan and the exhaust fan according to the temperature difference between the inside and the outside using the temperature detected by the temperature sensor. A temperature detection step of detecting an indoor temperature by an indoor temperature sensor and an outdoor temperature by an outdoor temperature sensor; A temperature difference detecting step of detecting a difference between indoor and outdoor temperatures detected by the temperature sensor in a controller; As a result of the temperature difference detection, if the temperature difference is less than a predetermined value, the controller opens the rapid exhaust duct so that the indoor air is discharged directly to the outside without passing the heat exchanger; And a heat exchange ventilation step of closing the rapid exhaust duct by the controller when the temperature difference is detected as a result of the temperature difference so that indoor air is discharged to the outside through the total heat exchanger. The method of claim 2, If the absolute value of the temperature difference is less than 5 in the temperature difference detection step, the rapid exhaust step is characterized in that the operating method of the ventilation device. The method of claim 2, If the absolute value of the temperature difference is 5 or more in the temperature difference detection step, the heat exchange ventilation step is characterized in that the operating method of the ventilation device. The method of claim 2, The heat exchange ventilating step includes a temperature comparing step in which the controller compares the outdoor temperature with a preset reference temperature, and an air volume adjusting step in which air flow rates of the air supply fan and the exhaust fan are differently operated according to the temperature comparison result. How to operate. The method of claim 5, wherein In the temperature comparison step, when the outdoor temperature is higher than 40 ° C., the controller operates the air supply fan and the exhaust fan in low wind to preserve the indoor temperature as much as possible. Operating method of the ventilation apparatus further comprising the step of driving. The method of claim 5, wherein In the temperature comparison step, when the outdoor temperature is lower than 20 ° C., the controller operates the air supply fan and the exhaust fan in low wind to preserve the indoor temperature as much as possible. Operating method of the ventilation apparatus further comprising the step of driving.

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