KR20190072136A - Ventilator and the control method thereof - Google Patents

Abstract

The present invention relates to a ventilation apparatus and a control method thereof, which are able to use a differential pressure of a flow path, in which outdoor air flows, in the ventilation apparatus and to more precisely determine whether a filter is clogged or not. To this end, according to the present invention, the ventilation apparatus comprises: a first exhaust chamber into which indoor air is introduced; a second exhaust chamber which discharges the indoor air passing through the first exhaust chamber to the outdoors; a first air supply chamber into which outdoor air is introduced; a second air supply chamber which supplies the outdoor air passing through the first exhaust chamber to the indoors; one or more filters to filter out the outdoor air flowing from the first air supply chamber to the second air supply chamber; a differential pressure sensor which measures a differential pressure of the outdoor air passing through the filters; and a control unit which determines whether the filters are clogged or not by using the differential pressure measured by the differential pressure sensor.

Description

TECHNICAL FIELD [0001] The present invention relates to a ventilator,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a ventilator and a control method thereof, and more particularly, to a ventilator and a control method thereof for detecting a clogging of a filter by sensing a differential pressure of the filter.

The indoor and outdoor air conditioners of the present invention are installed in a closed room to improve the cooling and heating efficiency, and the indoor air space is increased in pollution degree after a certain time, 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.

When the ventilator is used for a certain period of time, it is necessary to clean or replace the filter periodically because foreign substances are accumulated in the filter.

Generally, the prefilter is replaced at least once every 2 to 3 months, and the HEPA filter is replaced between 6 months to 1 year. The pre-filter that filters relatively large dust clogs ahead of the HEPA filter that filters the small dust, so the pre-filter has a shorter cleaning cycle than the HEPA filter.

However, the period of cleaning or replacement of these filters is greatly influenced by the ambient environment in which the ventilator is installed or by the weather. For example, in a region where a ventilation device is installed, when the dust generation amount is high or yellow dust frequently occurs, the period of cleaning or replacement of the filter is shortened. On the other hand, in the case where the amount of dust generated in the area where the ventilator is installed is low or yellow dust often does not occur, the period of cleaning or replacement of the filter becomes long.

In this way, the period of cleaning or replacement of the filter varies depending on the situation. Therefore, even if the filter performance is deteriorated due to a large amount of dust in the filter, the user can not recognize it, and the ventilation system can be continuously used with the ventilation performance deteriorated. In addition, when it is judged that the period of cleaning or replacement of the filter has arrived, it may take unnecessary time and cost if the state of the filter is good.

Korean Patent Registration No. 10-0706881 is disclosed as a conventional technique for solving such a problem. In the related art, the filter replacement period is determined by using either the voltage or the current applied to the fan motor. However, in such a case, there is a problem that it is difficult to accurately determine the filter replacement cycle because the voltage, current, etc. applied to the fan motor in which foreign substances such as dust accumulate in the rotating shaft of the fan motor or the fan can be varied.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a ventilation apparatus and a control method thereof that can more accurately determine clogging of a filter by utilizing a differential pressure of a flow path through which outdoor air flows in a ventilator. There is a purpose.

It is another object of the present invention to provide a ventilation device and a control method thereof that can simultaneously determine whether a plurality of filters are blocked or not.

It is another object of the present invention to provide a ventilation device and a control method thereof capable of determining clogging of a filter without being affected by foreign matter contained in outdoor air.

Another object of the present invention is to provide a control method of a ventilator which can distinguish between a case in which a filter needs to be replaced and a case in which cleaning is required, It is in the cage.

According to an aspect of the present invention, there is provided a ventilation system including a first exhaust chamber into which indoor air flows, a second exhaust chamber through which indoor air passed through the first exhaust chamber is discharged to the outside, And a second air supply chamber for supplying outdoor air via the first air supply chamber to the room, wherein the first air supply chamber is connected to the first air supply chamber and the second air supply room, One filter; A differential pressure sensor for measuring differential pressure of outdoor air passing through the filter; And a controller for determining clogging of the filter using the differential pressure measured by the differential pressure sensor.

Wherein the filter is composed of a plurality of filters positioned between the first air supply chamber and the second air supply chamber and including a first filter closest to the first air supply chamber and a second filter closest to the second air supply chamber under; One end of the pressure measuring pipe in which the differential pressure sensor is installed communicates with the front of the first filter and the other end of the pressure measuring pipe communicates with the rear of the second filter.

A total enthalpy heat exchanger in which heat exchange is performed between indoor air flowing from the first exhaust chamber to the second exhaust chamber and outdoor air flowing from the first feed chamber to the second air supply chamber; Wherein the first filter is provided on one side of the total enthalpy heat exchanger facing the first air supply chamber and the second filter is provided between one side of the first filter and the total enthalpy heat exchanger, Filtering foreign substances contained in the air; The other end of the pressure measuring pipe may be installed to communicate with a space between the second filter and the total enthalpy heat exchanger.

Wherein one end of the pressure measurement pipe in which the differential pressure sensor is installed communicates with an external space of the ventilation device and the other end of the pressure measurement pipe is provided so that the outdoor air communicates with the rear of the filter through the filter, can do.

Wherein the filter is composed of a plurality of filters positioned between the first air supply chamber and the second air supply chamber and including a first filter closest to the first air supply chamber and a second filter closest to the second air supply chamber under; And the other end of the pressure measuring pipe may be installed to communicate with the rear of the second filter among the plurality of filters.

A total enthalpy heat exchanger in which heat exchange is performed between indoor air flowing from the first exhaust chamber to the second exhaust chamber and outdoor air flowing from the first feed chamber to the second air supply chamber; Wherein the first filter is provided on one side of the total enthalpy heat exchanger facing the first air supply chamber and the second filter is provided between one side of the first filter and the total enthalpy heat exchanger, Filtering foreign substances contained in the air; The other end of the pressure measuring pipe may be installed to communicate with a space between the second filter and the total enthalpy heat exchanger.

The outer space of the ventilator through which the one end of the pressure measuring pipe communicates may be an outdoor unit room located between the outdoor unit and the indoor unit.

The external space of the ventilation device, through which one end of the pressure measurement pipe communicates, may be the room.

And an alarm generating unit for generating an alarm when it is determined that the filter is clogged from the differential pressure measured by the differential pressure sensor.

The first filter may be a pre-filter, and the second filter may be a HEPA filter.

A control method of a ventilator according to the present invention comprises the steps of: a) measuring a differential pressure in at least one filter for filtering outdoor air flowing into a room by a differential pressure sensor; b) determining whether the differential pressure measured by the differential pressure sensor meets a preset reference value; and c) generating an alarm by determining that the filter is clogged when the measured differential pressure satisfies the reference value.

Wherein when a first alarm occurs before the step a) and thereafter the control of the steps a) to c) is additionally performed so that the alarm occurs secondarily, a first elapsed time until the first alarm occurs, Wherein when the second elapsed time is shorter than the first elapsed time, information indicating that replacement of the filter is necessary is included in the second alarm .

The primary alarm may include information that the filter needs to be cleaned.

The primary alarm may be a periodic alarm for generating an alarm at each set time to inform the periodic check of the filter.

In this case, the plurality of filters may be formed, and the differential pressure sensor may measure the differential pressure of outdoor air passing through the plurality of filters.

According to the present invention, the clogging of the filter can be determined more accurately by utilizing the differential pressure of the flow path through which the outdoor air flows.

In addition, it is possible to make an accurate judgment on the filter cleaning or replacement cycle by simultaneously determining whether the plurality of filters are clogged.

Further, it is possible to prevent the occurrence of errors in the differential pressure measurement due to the turbulence generated when the dust or outdoor air contained in the outdoor air flows, so that the clogging of the filter can be accurately determined.

In addition, by comparing the elapsed time between a plurality of alarms to generate different alarms, it is possible to distinguish between a case where a filter is required to be replaced and a case where a filter is required to be cleaned. Thus, have.

1 is a schematic plan view of a ventilator according to the present invention;
Figure 2 is a cross-sectional view taken along the line AA of Figure 1 showing the differential pressure sensor of the present invention.
3 is a schematic plan view of a ventilator according to another embodiment of the present invention;
Figure 4 is a cross-sectional view taken along the line AA of Figure 3 showing the differential pressure sensor of the present invention
5 is a flowchart showing a control method of a ventilator according to the present invention.

Hereinafter, a ventilator according to the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, a ventilator 1 according to the present invention includes a first exhaust chamber 10 through which indoor air flows, a second indoor chamber 12 through the first exhaust chamber 10, A second exhaust chamber 20 for exhausting air to the outside, a first air supply chamber 30 for receiving outdoor air, a second air supply chamber (not shown) for supplying outdoor air via the first air supply chamber 30 to the room At least one filter 60 for filtering the outdoor air flowing from the first air supply chamber 30 to the second air supply chamber 40 and a pressure sensor for measuring the differential pressure of the outdoor air passing through the filter 60 And a control unit (not shown) for determining clogging of the filter 60 by using a differential pressure measured by the differential pressure sensor 100.

An indoor air inlet (11) through which indoor air flows is provided on the indoor side of the first exhaust chamber (10). A ventilation damper 12 for opening and closing the flow path of the indoor air inlet 11 may be provided.

And an indoor air outlet 21 through which indoor air is discharged to the outdoor side is provided on the outdoor side of the second exhaust chamber 20. [ The second exhaust chamber 20 may be provided with an exhaust blower 22 for forcibly sucking room air outdoors.

An outdoor air inlet (31) through which outdoor air flows is provided on the outdoor side of the first air supply room (30). An outside air damper (32) for opening and closing a flow path through which outdoor air flows may be provided inside the outdoor air inlet (31).

An outdoor air outlet (41) through which the outdoor air is discharged to the indoor side is provided on the indoor side of the second air supply room (40). The second air supply chamber (40) may be provided with an air supply fan (42) for forcibly sucking outdoor air to the indoor side.

A total enthalpy heat exchanger (not shown) for exchanging heat between indoor air flowing from the first exhaust chamber 10 to the second exhaust chamber 20 and outdoor air flowing from the first air supply chamber 30 to the second air supply chamber 40 50 may be provided. 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 plurality of operation modes including a ventilation mode may be set in the control unit, and operation is performed in the set operation mode while controlling the operation of each of the above configurations.

The filter 60 may be provided on one side of the total enthalpy heat exchanger 50 facing the first feed chamber 30. In this case, the filter 60 filters the foreign substances contained in the air flowing into the total enthalpy heat exchanger 50.

The filter 60 may be a variety of filters such as a HEPA filter, a prefilter, a medium filter, and a deodorization filter, and one or a plurality of filters may be applied. The plurality of filters 60 may be composed of a prefilter 61 located on the first feed chamber 30 side and a HEPA filter 62 located on the side of the total enthalpy heat exchanger 50 .

Referring to FIG. 2, the differential pressure sensor 100 senses the differential pressure generated when the outdoor air passes through the plurality of filters 61 and 62 located between the first and second feed chambers 30 and 40 .

In the present embodiment, the plurality of filters 61 and 62 exemplify the two prefilters 61 and the HEPA filter 62. However, when three or more filters are provided, the differential pressure sensor 100 detects the outdoor air And measuring the differential pressure generated while passing through the three or more filters.

The differential pressure sensor 100 is disposed between the front end of the first filter 61 closest to the first feed chamber 30 and the front end of the first filter 61 closest to the second feed chamber 40 The pressure difference between the rear end of the second filter 62 installed can be measured.

The differential pressure sensor 100 is installed on the pressure measurement pipe 110 and one end portion 101 of the pressure measurement pipe 110 is connected to the first feed chamber 101 of the plurality of filters 61, And the other end 102 of the pressure measurement pipe 110 communicates with the space inside the first feed chamber 30 which is located in front of the first filter 61 closest to the second feed chamber 40 To the space (S1) between the second filter (62) which is the rear of the second filter (62) closest to the first filter (62) and the total enthalpy heat exchanger (50).

If the differential pressure measured from the differential pressure sensor 100 satisfies the differential pressure reference value, it can be determined that the filter is clogged.

And an alarm generating unit (not shown) for generating an alarm when the control unit determines that the filter is blocked. The alarm generator can recognize the clogging of the filter by the user in various ways such as a sound or a character.

According to the above configuration, since the differential pressure sensor 100 is used, when a foreign substance such as dust accumulates on the rotating shaft of the conventional fan motor or the fan, the problem of measurement error due to the change of the voltage, So that the clogging of the filter can be accurately determined.

Further, when the outdoor air passes through the plurality of filters 61 and 62, it is possible to accurately determine whether or not the filters 61 and 62 are blocked.

For example, if the second filter 62 is clogged and only the pressure difference before and after the first filter 61 is measured when the first filter 61 is not blocked, the second filter 62 is actually clogged, It may not be judged that the filter is clogged even though the ventilation performance is deteriorated.

When the second filter 62 is not clogged and the first filter 61 is blocked, only the pressure difference between before and after the second filter 62 is measured. In fact, the first filter 61 is clogged and the ventilation performance of the ventilator It may not be judged that the filter is clogged.

In this case, when it is desired to determine clogging in the first filter 61 and the second filter 62, two differential pressure sensors should be provided.

However, according to the present invention, the differential pressure sensor 100 measures the differential pressure generated when the outdoor air passes through the plurality of filters 61 and 62, so that only one of the filters 61 and 62 is clogged A change in the differential pressure occurs. Therefore, from the change in the differential pressure, it can be judged that the filter is clogged in the control section. Furthermore, even if a plurality of differential pressure sensors are not provided, it is possible to determine whether the plurality of filters 61 and 62 are blocked by only one differential pressure sensor 100. [ Therefore, it is possible to make an accurate judgment on the cleaning or replacement cycle of the filters 61 and 62 with a simple configuration.

In this embodiment, the other end 102 of the pressure measuring pipe 110 is configured to communicate with the space S1 between the second filter 62 and the total enthalpy heat exchanger 50, And the other end 102 of the second feed chamber 40 communicates with the second feed chamber 40. In this case, the accuracy of the differential pressure measurement may be lower than when the other end 102 of the pressure measurement pipe 110 is configured to communicate with the space S1 between the second filter 62 and the total enthalpy heat exchanger 50. [

That is, the second air supply chamber 40 is provided with the air supply blower 42. When the air supply fan (42) is activated, outdoor air can be formed around the air supply fan (42). In order to accurately measure the differential pressure in the differential pressure sensor 100, a positive pressure must be applied, except for the dynamic pressure. As described above, when the outdoor air is turbulent, dynamic pressure acts on the differential pressure sensor 100, so it is difficult to accurately measure the differential pressure. Furthermore, since the first filter 61 is provided in front of the space S1 and the total enthalpy heat exchanger 50 is provided in the rear of the space S1, turbulence of outdoor air can be suppressed in the front and rear of the space S1. The accuracy of the differential pressure measurement can be improved by configuring the other end 102 of the pressure measurement pipe 110 to communicate with the space S1 between the second filter 62 and the total enthalpy heat exchanger 50. [

The ventilator 1 according to another embodiment of the present invention will be described with reference to Figs. 3 and 4. Fig.

The ventilator 1 of the present embodiment is installed in an outdoor unit room formed between the room and the outside and has first to fourth ducts 71, 72, 73 and 74, 1 and Fig. 2 in that the end portion 101 communicates with the internal space of the outdoor unit room, and the rest of the configuration can be equally applied.

The first duct 71 is connected to the indoor air inlet 11 and the second duct 72 is connected between the indoor air outlet 21 and the outdoor air. (73), and the fourth duct (74) is connected between the outdoor air outlet (41) and the room.

One end portion 101 of the pressure measurement pipe 110 in which the differential pressure sensor 100 is installed communicates with the outdoor unit space which is the outer space of the ventilation device 1 and the other end portion (102) communicates with the space (S1) between the second filter (62) and the total enthalpy heat exchanger (50).

The outdoor unit room includes a third duct 73, a first air supply chamber 30, a total heat exchanger 50, a second air supply chamber 40, a fourth duct (not shown), which is a flow path through which outdoor air flows in the ventilator 1, (74).

Therefore, when the one end portion 101 of the pressure measurement pipe 110 is configured to communicate with the outdoor unit room, there is no air flow in the outdoor unit room, so that only the positive pressure acts on the differential pressure sensor 100 , The accuracy of the differential pressure measurement can be improved. In addition, since outdoor air does not flow into the outdoor unit, dust or the like is not accumulated at one end portion 101 of the pressure measurement pipe 110, thereby preventing malfunction of the differential pressure sensor 100.

In this case, when the ventilator (1) is installed in the room other than the outdoor room, one end (101) of the pressure measuring pipe (110) may be configured to communicate with the room. That is, the external space of the ventilator may be an interior space through which the first exhaust chamber 10 or the second air supply chamber 40 communicates. In this case, it is preferable that one end portion 101 of the pressure measurement pipe 110 is connected to a position that is not affected by the flow of indoor air or outdoor air when the ventilator is operated in the ventilation mode. With this configuration, the room where the ventilator 1 is installed is not subjected to the dynamic pressure due to the flow of air, but acts only on the positive pressure, so that the accuracy of the differential pressure measurement can be improved. Since the outside air after the dust is filtered by the filter 60 flows into the room, there is no fear that dust or the like will accumulate on one end portion 101 of the pressure measuring pipe 110, thereby causing malfunction of the differential pressure sensor 100.

Although the ventilator 1 including the total enthalpy heat exchanger 50 has been described in the above embodiments, the configuration for measuring the pressure difference of the present invention is also applicable to the ventilator not including the total enthalpy heat exchanger 50.

A control method of the ventilator of the present invention will be described with reference to Fig.

Step S201 is a step of measuring the differential pressure of the outdoor air passing through the filter 60 from the differential pressure sensor 100. [ The differential pressure information measured by the differential pressure sensor 100 is received by the control unit.

In step S202, the controller determines whether the measured differential pressure meets the differential pressure reference value. If the measured differential pressure satisfies the differential pressure reference value, it is determined that the filter is clogged, and the process proceeds to step S203. Otherwise, the process proceeds to step S201.

Step S203 is a step of generating a primary alarm at the alarm generating unit. The primary alarm may include information that the filter 60 needs to be cleaned. When the primary alarm occurs in this manner, the user recognizes the necessity of cleaning the filter 60 and cleans the filter 60. In this case, the control unit may measure and store a first elapsed time, which is an elapsed time until a first alarm occurs, in a timer (not shown). If the first alarm is generated for the first time, the first elapsed time may be set to the elapsed time from when the ventilator 1 is installed until the first alarm occurs.

Steps S204 and S205 measure the differential pressure in the filter 60 in the same manner as described above to determine whether or not the differential pressure reference value is met. If the measured differential pressure satisfies the differential pressure reference value as a result of the determination, the process proceeds to step S206, and if not, the process proceeds to step S204.

Step S206 is a step of comparing the first elapsed time with the second elapsed time to determine whether the elapsed time is shortened.

Which is the elapsed time from when the primary alarm occurs to when the determination in step S205 is made (i.e., the elapsed time from the occurrence of the primary alarm to the occurrence of the secondary alarm of steps S207 and S208) Time is measured in the timer. If the elapsed time is shortened because the second elapsed time is shorter than the first elapsed time by comparing the first elapsed time and the second elapsed time, the contamination of the filter 60 is not solved by cleaning, It is determined that replacement of the filter 60 is necessary and the process proceeds to step S207. Otherwise, it is determined that the filter 60 needs to be cleaned, and the process proceeds to step S208.

Step S207 is a step of generating a replacement alarm that requires replacement for the filter 60, and step S208 is a step of generating a cleaning alarm that the cleaning of the filter 60 is necessary.

The replacement alarm and the cleaning alarm can be implemented by the alarm generating unit so that the user can distinguish in various ways. For example, it may be provided as character information, voice information for replacement or cleaning, or may provide information about replacement or cleaning with the color of the alarm lamp.

In the above description, the case in which the pressure difference in the filter 60 is measured a plurality of times and each elapsed time is compared is explained. However, the first alarm may be an alarm for the filter inspection periodically Or a periodic alarm to be generated.

For example, when the set time of 4000h elapses, a periodical alarm is generated to check whether the filter 60 needs to be cleaned or exchanged. If the differential pressure measured after 2000h or 3000h elapses after the regular alarm is generated meets the differential pressure reference value The secondary alarm may be configured as a replacement alarm including information that the filter 60 needs to be replaced.

When the filter 60 is determined to be clogged in this way, it is possible to distinguish between the case where the filter 60 needs to be replaced and the case where the filter 60 needs to be cleaned. Thus, the user can select a proper inspection method, Can be improved. In particular, when the filter 60 is composed of a plurality of filters including the prefilter 61 and the HEPA filter 62, it is determined whether to clean the prefilter 61 or replace the HEPA filter 62 according to the type of the alarm And it becomes easy to check the filter.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And this also belongs to the present invention.

1: Ventilation device 10: First exhaust chamber
11: indoor air inlet 12: ventilation damper
20: second exhaust chamber 21: room air outlet
22: exhaust blower 30: first class room
31: outdoor air inlet 32: outdoor damper
40: second class room 41: outdoor air outlet
42: blower for air supply 50: total heat exchanger
60: filter 61: prefilter
62: HEPA filter 71: First duct
72: second duct 73: third duct
74: fourth duct 100: differential pressure sensor
110: Pressure measuring tube

Claims (15)

A first exhaust chamber through which indoor air flows, a second exhaust chamber through which indoor air passed through the first exhaust chamber is exhausted to the outside, a first exhaust chamber into which outdoor air flows, an outdoor air passing through the first exhaust chamber And a second air chamber for supplying air into the room,
At least one filter for filtering outdoor air flowing from the first feed chamber to the second feed chamber;
A differential pressure sensor for measuring differential pressure of outdoor air passing through the filter;
A controller for determining clogging of the filter using the differential pressure measured by the differential pressure sensor;
Lt; RTI ID = 0.0 > The method according to claim 1,
Wherein the filter is composed of a plurality of filters positioned between the first air supply chamber and the second air supply chamber and including a first filter closest to the first air supply chamber and a second filter closest to the second air supply chamber under;
Wherein one end of the pressure measuring pipe in which the differential pressure sensor is installed communicates with the front of the first filter and the other end of the pressure measuring pipe communicates with the rear of the second filter, 3. The method of claim 2,
A total enthalpy heat exchanger in which heat exchange is performed between indoor air flowing from the first exhaust chamber to the second exhaust chamber and outdoor air flowing from the first feed chamber to the second air supply chamber;
Wherein the first filter is provided on one side of the total enthalpy heat exchanger facing the first air supply chamber and the second filter is provided between one side of the first filter and the total enthalpy heat exchanger, Filtering foreign substances contained in the air;
And the other end of the pressure measuring pipe is installed so as to communicate with a space between the second filter and the total enthalpy heat exchanger. The method according to claim 1,
Wherein one end of the pressure measurement pipe in which the differential pressure sensor is installed communicates with an external space of the ventilation device and the other end of the pressure measurement pipe is provided so that the outdoor air communicates with the rear of the filter through the filter, And a ventilation device 5. The method of claim 4,
Wherein the filter is composed of a plurality of filters positioned between the first air supply chamber and the second air supply chamber and including a first filter closest to the first air supply chamber and a second filter closest to the second air supply chamber under;
And the other end of the pressure measuring pipe is provided so as to communicate with the rear of the second filter among the plurality of filters. 6. The method of claim 5,
A total enthalpy heat exchanger in which heat exchange is performed between indoor air flowing from the first exhaust chamber to the second exhaust chamber and outdoor air flowing from the first feed chamber to the second air supply chamber;
Wherein the first filter is provided on one side of the total enthalpy heat exchanger facing the first air supply chamber and the second filter is provided between one side of the first filter and the total enthalpy heat exchanger, Filtering foreign substances contained in the air;
And the other end of the pressure measuring pipe is installed so as to communicate with a space between the second filter and the total enthalpy heat exchanger. 5. The method of claim 4,
Wherein an outer space of the ventilator in which one end of the pressure measuring pipe is communicated is an outdoor unit room located between the outdoor unit and the indoor unit. 5. The method of claim 4,
Characterized in that the external space of the ventilator in which the one end of the pressure measuring tube communicates is the inside of the ventilator The method according to claim 1,
And an alarm generating unit for generating an alarm when it is determined that the filter is clogged from the differential pressure measured by the differential pressure sensor. 6. The method according to claim 2 or 5,
Wherein the first filter is a pre-filter and the second filter is a HEPA filter. a) measuring a differential pressure in at least one filter for filtering outdoor air flowing into a room by a differential pressure sensor;
b) determining whether the differential pressure measured by the differential pressure sensor meets a preset reference value;
c) generating an alarm by determining that the filter is clogged when the measured differential pressure satisfies the reference value;
A control method of a ventilator comprising 12. The method of claim 11,
Wherein when a first alarm occurs before the step a) and thereafter the control of the steps a) to c) is additionally performed so that the alarm occurs secondarily, a first elapsed time until the first alarm occurs, Wherein when the second elapsed time is shorter than the first elapsed time, information indicating that replacement of the filter is necessary is included in the second alarm A control method of a ventilating apparatus 13. The method of claim 12,
Wherein the first alarm includes information indicating that the filter needs to be cleaned 13. The method of claim 12,
Wherein the primary alarm comprises a periodic alarm for generating an alarm at each set time to inform the periodic check of the filter 13. The method of claim 12,
Characterized in that a plurality of said filters are provided, and said differential pressure sensor measures a differential pressure of outdoor air passing through a plurality of filters

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