KR102320226B1 - Method for informing user the time of filter exchange in heat exchanger - Google Patents

Abstract

The present invention relates to a method for notifying a filter replacement time of a total heat exchanger, and the present invention relates to a total heat exchanger comprising a housing, a heat exchange element, a constant airflow blower for supply air, a constant airflow blower for exhaust, a filter unit, a notification unit, and a control unit. , operating the constant airflow blower and the constant airflow blower for exhaust, respectively; detecting the number of rotations of the constant airflow blower for supplying air; detecting whether the rotational speed of the constant airflow blower for supplying air rotates in a set rotational speed region; and generating a notification for filter replacement when the rotational speed of the constant airflow blower for supplying air rotates at a rotational speed greater than a set rotational speed region. According to the present invention, it not only prevents overload by the filter constituting the total heat exchanger, but also informs the manager of the optimal time to replace the filter, which prevents waste of the filter.

Description

How to notify the filter replacement time of total heat exchanger {METHOD FOR INFORMING USER THE TIME OF FILTER EXCHANGE IN HEAT EXCHANGER}

The present invention relates to a method for notifying a filter replacement time of a total heat exchanger.

In general, sand winds occur in the desert regions inside the Asian continent between March and May, and they are blown to the Northeast Asian region under the influence of the westerly wind, causing enormous damage to the Northeast Asian region. In addition, in recent years, various heavy metal fines such as sulfur dioxide, nitrogen oxide, lead, ozone, and carbon monoxide, which have dramatically increased in the process of industrialization in China, are causing enormous damage to Northeast Asia including Korea.

When such yellow dust and fine dust are introduced into the interior of a building, it not only causes respiratory diseases of people living in the interior of the building, but also adversely affects health.

On the other hand, if a person is active for a long time indoors in a state where the interior of a building where people live is not well ventilated from the outside, it is impossible to maintain a comfortable state due to indoor air pollution and increase in CO2, so it is necessary to ventilate the interior. If the window is opened to ventilate, pollutants such as yellow dust and fine dust enter, as well as internal heat loss. In order to solve this problem, a ventilation system provided with a total heat exchanger that filters outside air while exchanging heated indoor air discharged to the outside and cold outdoor air flowing into the room is provided in a building. As such, the total heat exchanger of the building ventilation system is provided with a filter assembly that removes foreign substances contained in the outside air when the outside air is introduced.

Since the filter assembly of the building ventilation system having such a total heat exchanger filters yellow dust and fine dust, the filter of the filter assembly must be replaced. If the filter of the filter assembly is not replaced in a timely manner, not only will the blower for air supply of the total heat exchanger be overloaded, but also shade will be generated in the room, causing external fine dust to flow into the room, and the filter of the filter assembly will be replaced frequently. In this case, there is a problem that not only the maintenance cost is high, but also the maintenance is inconvenient.

An object of the present invention is to provide a filter replacement time notification method of a total heat exchanger that not only prevents overload by the filters constituting the total heat exchanger, but also informs the manager of the optimal filter replacement time to prevent waste of filters.

In order to achieve the object of the present invention, an indoor air supply port and an indoor exhaust port are provided on a first side plate, which is one side plate, and an outdoor side air supply port and an outdoor side exhaust port are provided on the second side plate, which is the other side plate facing the first side plate. An exhaust passage through which the indoor air is discharged to the outdoors by communicating the indoor exhaust port and the outdoor exhaust port inside, and an air supply passage through which the outdoor air flows into the room by communicating the indoor and outdoor air supply ports inside provided housing; a heat exchange element mounted inside the housing to exchange heat between indoor air discharged through an exhaust passage and outdoor air flowing into an air supply passage; a constant airflow blower for supplying air that is provided in the air supply passage adjacent to the indoor air supply port to generate an inflow flow; a constant air volume blower for exhaust which is provided in the exhaust passage adjacent to the outdoor exhaust port to generate an exhaust flow; a filter unit provided in the air supply passage of the housing to filter outside air; a notification unit notifying the filter replacement time of the filter unit; and a control unit including a control that detects rotation of the constant airflow blower for supply and the constant airflow blower for exhaust and generates a notification of the notification unit when the number of rotations is greater than or equal to a set value, wherein the constant airflow blower for supply and exhaust In the total heat exchanger comprising a pre-filter, a medium filter, and a HEPA filter, each of the constant airflow blowers includes a BLDC motor and an impeller rotated by the BLDC motor,

The constant air volume blower for supply air and the constant air volume blower for exhaust are respectively operated, and the rotational speed of the constant air volume blower for supply air is set so that the blowing amount of the constant air volume blower for supply air is greater than that of the constant air volume blower for exhaust. operating the blower greater than the rotation speed; detecting the rotational speed of the constant airflow blower for supply air and monitoring whether the rotational speed of the constant airflow blower for supplying air rotates in a set rotational speed region; There is provided a filter replacement time notification method of a total heat exchanger comprising; generating a notification for filter replacement when the rotation speed of the constant airflow blower for supplying air rotates at a rotation speed greater than a set rotation speed region.

In addition, an indoor air supply port and an indoor exhaust port are provided on a first side plate, which is one side plate, and an outdoor side air supply port and an outdoor side exhaust port are provided on the second side plate, which is the other side plate facing the first side plate, a housing provided with an exhaust passage through which the indoor air is discharged to the outdoors by communicating the side exhaust port and the outdoor exhaust port, and an air supply passage through which the outdoor air flows into the room by communicating the indoor air supply port and the outdoor air supply port therein; a heat exchange element mounted inside the housing to exchange heat between indoor air discharged through an exhaust passage and outdoor air flowing into an air supply passage; a constant airflow blower for supplying air that is provided in the air supply passage adjacent to the indoor air supply port to generate an inflow flow; a constant air volume blower for exhaust which is provided in the exhaust passage adjacent to the outdoor exhaust port to generate an exhaust flow; a filter unit provided in the air supply passage of the housing to filter outside air; a notification unit notifying the filter replacement time of the filter unit; and a control unit including a control that detects rotation of the constant airflow blower for supply and the constant airflow blower for exhaust and generates a notification of the notification unit when the number of rotations is greater than or equal to a set value, wherein the constant airflow blower for supply and exhaust In the total heat exchanger comprising a pre-filter, a medium filter, and a HEPA filter, each of the constant airflow blowers includes a BLDC motor and an impeller rotated by the BLDC motor,

operating the constant airflow blower for supply and the constant airflow blower for exhaust, respectively; detecting the rotational speed of the constant airflow blower for supply air and monitoring whether the rotational speed of the constant airflow blower for supplying air rotates in a set rotational speed region; A filter setting step of setting replacement timing of the pre-filter, medium filter, or HEPA filter constituting the filter unit when the rotation speed of the constant airflow blower for the supply air is rotated at a rotation speed greater than the set rotation speed region; In the filter setting step, the air volume generated in the first reference rotation speed region of the constant air volume blower for supplying air is referred to as the first air volume, and the air volume generated in the second reference rotation speed region smaller than the first reference rotation speed region is selected. When the second air volume is referred to as the third air volume and the air volume generated in the third reference speed area smaller than the second reference speed area is referred to as the third air volume, in the state where the first air volume is set, the air volume is greater than or equal to the first reference speed range When this is detected, a notification to replace the HEPA filter is generated, and when an abnormality is detected in the second reference rotation speed range in a state where the second air volume is set, a notification to replace the medium filter is generated, and the third air volume is set There is provided a filter replacement time notification method of a total heat exchanger, characterized in that when an abnormality is detected in the third reference rotation speed range in one state, a notification to replace the pre-filter is generated.

Preferably, the first, second, and third air volumes are 200CMH, 150CMH, and 100CMH, respectively, and the first, second, and third reference rotational speed regions are 2670-2770 RPM, 2460-2560 RPM, and 2100-2200 RPM, respectively.

It is preferable to operate the rotational speed of the constant airflow blower for supplying air to be greater than the rotational speed of the constant airflow blower for exhaust so that the blowing amount of the constant airflow blower for supplying air is greater than that of the exhaust constant airflow blower.

The filter replacement time notification method of the total heat exchanger according to the present invention, when the constant airflow blower for supply of the total heat exchanger supplies outdoor air to the indoor air, the outdoor air is filtered through the filter unit and continuously supplied into the indoor air. As dust and foreign substances accumulate on the filter unit, the filter unit becomes clogged, and when the filter unit is gradually clogged and cannot perform the proper function according to the experimental values, the manager is notified of the replacement time of the filter unit. At this point, the filter unit will be replaced. Due to this, not only prevents overload of the constant airflow blower for air supply by the filter unit, but also prevents waste of the filter and facilitates maintenance.

In addition, in the present invention, when the filter unit includes a pre-filter, a medium filter, and a HEPA filter, it is possible to replace the pre-filter, medium filter, and HEPA filter at an optimal time by notifying the appropriate replacement time of each filter. It is possible to prevent waste and maintain the proper filtration performance of the filter unit.

1 is a plan sectional view showing an example of a total heat exchanger according to the present invention;
2 is a front view showing an example of a total heat exchanger according to the present invention;
3 is a flowchart showing a first embodiment of a method for notifying a filter replacement time of a total heat exchanger according to the present invention;
Figure 4 is a flow chart showing a second embodiment of the filter replacement time notification method of the total heat exchanger according to the present invention.

Hereinafter, an embodiment of a filter replacement time notification method of a total heat exchanger according to the present invention will be described with reference to the accompanying drawings.

1 is a plan sectional view showing an example of a total heat exchanger according to the present invention. 2 is a front view showing an example of a total heat exchanger according to the present invention.

1 and 2, an embodiment of the total heat exchanger according to the present invention includes a housing 100, a heat exchange element 200, a constant air volume blower 300 for supply air, and a constant air volume blower 400 for exhaust. , a filter unit 500 , a notification unit 600 , and a control unit 700 .

The housing 100 is connected to each other and covers the top and bottom of the front, rear, left, and right plates 110, 120, 130, 140 and the front, rear, left, and right plates to form a quadrangle. It includes upper and lower plates 150 and 160 that form a space, and an indoor air supply port 131 and an indoor exhaust port 132 are provided on the left plate 130 , and the outdoor supply port 131 is provided on the right plate 140 . A mechanism 141 and an outdoor exhaust port 142 are provided. The front, rear, left, and right positions of the housing 100 are set with reference to FIG. 1 for convenience of description. Hereinafter, the left plate 130 is called a first side plate and the right plate 140 is called a second side plate. The indoor air inlet 131 of the first side plate 130 and the outdoor exhaust 142 of the second side plate 140 are positioned to face each other, and the indoor exhaust 132 of the first side plate 130 and the second The outdoor air inlet 141 of the second side plate 140 is positioned to face each other. The air supply flow path P1 is formed inside the housing 100 to communicate the indoor air supply port 131 of the first side plate 130 and the outdoor air supply port 141 of the second side plate 140 , and the first An exhaust passage P2 is formed to communicate the indoor exhaust port 132 of the side plate 130 and the outdoor exhaust port 142 of the second side plate 140 . The housing 100 is installed in a building so that the indoor air supply port 131 and the indoor exhaust port 132 communicate with the indoor side of the building, and the outdoor air supply port 141 and the outdoor exhaust port 142 communicate with the outdoor side of the building. communicates with

The heat exchange element 200 is mounted inside the housing 100 so that the supply air passage P1 and the exhaust passage P2 are respectively connected to each other, and the outdoor air introduced into the supply air passage P1 and the indoor air discharged through the exhaust passage P2 are respectively connected to each other. heat exchange with air. The heat exchange element 200 has a hexahedral shape, and the four corners of the heat exchange element 200 are front and rear of the housing 100 , respectively, and the middle of the first and second side plates 110 , 120 , 130 , 140 . It is located inside the housing 100 so as to be located in the portion. Front, rear, first, second side plates 110, 120, 130, 140 is provided with a partition wall (W) in the middle of each of the corners of the heat exchange element 200 is supported by the partition wall (W). . As the heat exchange element 200 is positioned inside the housing 100 , four compartment spaces S are provided inside the housing 100 . Each of the four compartments communicates with the indoor air inlet 131 , the indoor exhaust 132 , the outdoor air inlet 141 , and the outdoor exhaust 142 , respectively.

The constant air volume blower 300 for air supply is installed in the compartment S communicating with the indoor air supply port 131 , and the outlet of the constant air volume blower 300 for air supply is connected to the indoor air supply port 131 .

The constant air volume blower 400 for exhaust is installed in the partition space (S) communicating with the outdoor exhaust port 142, and the discharge port of the constant air volume blower 400 for exhaust is the outdoor exhaust port ( 142) is connected.

The constant air volume blower 300 for supply air and the constant air volume blower 400 for exhaust are respectively provided in the fan housing 5 provided with the inlet 1 and the outlet 2, and the fan housing 5 and rotated. and an impeller 6 for generating an air flow in which air is sucked into the suction port 1 and discharged to the discharge port 2 by the air, and a motor 7 for rotating the impeller 6 . The motor 7 is preferably a BLDC motor. When the impeller 6 is rotated by the driving force of the BL DC motor 7 , a flow (wind force) is generated by the rotational force of the impeller 6 , and the air sucked through the suction port 1 passes through the fan housing 5 . It is discharged through the discharge port (2).

The filter unit 500 is provided in the air supply passage P1 of the housing 100 to filter the outside air. The filter unit 500 preferably includes a pre-filter 510 , a medium filter 520 , and a HEPA filter 530 . The pre-filter 510 and the medium filter 520 are located in the partition space S communicating with the outdoor air inlet 141, and are mounted to be located on one side of the heat exchange element 200, and the pre-filter 510 is spaced apart from one side of the heat exchange element 200 , and a medium filter 520 is located between the pre-filter 510 and one side of the heat exchange element 200 . The HEPA filter 530 is positioned in the partition space S communicating with the indoor air inlet 131 and is mounted to be positioned on the other side of the heat exchange element 200 .

The notification unit 600 notifies the user of the filter replacement time of the filter unit 500 . The notification unit 600 may include a display displayed visually, and may also include an alarm displayed by sound.

The control unit 700 detects the rotation of the constant airflow blower 300 for supply and the constant airflow blower 400 for exhaust and generates a notification of the notification unit 600 if the number of rotations is greater than or equal to a set value.

3 is a flowchart illustrating a first embodiment of a method for notifying a filter replacement time of a total heat exchanger according to the present invention.

As shown in FIG. 3 , in the first embodiment of the method for notifying the filter replacement timing of the total heat exchanger, first, the constant air volume blower 300 for supply air and the constant air volume blower 400 for exhaust are respectively controlled by the control unit 700 . The driving step (S1) proceeds. When the constant air volume blower 300 for supply air and the constant air volume blower 400 for exhaust are operated, respectively, the external air is introduced through the outdoor air supply port 141 by the suction power of the constant air volume blower 300 for supply air and is supplied. It flows into the room through the indoor air supply port 131 through the flow path P1, the filter unit 500, and the heat exchange element 200, and the indoor air is moved indoors by the suction power of the constant airflow blower 400 for exhaust. It is discharged to the outside through the outdoor exhaust port 142 while passing through the exhaust port 132, the exhaust passage P2, and the heat exchange element 200, and the external air flowing into the room from the heat exchange element 200 and the indoor exhausted to the outdoors. heat exchange of air takes place. External air flowing in through the outdoor air supply port 141 by the suction power of the constant airflow blower 300 for supply air passes through the filter unit 500, and fine dust and foreign substances mixed with the external air enter the filter unit 500. Filtered and clean air is introduced into the room. The pre-filter 510, the medium filter 520, and the HEPA filter 530 of the filter unit 500 filter large foreign substances, medium-sized foreign substances, and fine-sized foreign substances, respectively.

When the constant air volume blower 300 for supply air and the constant air volume blower 400 for exhaust are operated, respectively, the airflow amount of the constant air volume blower 300 for supply air is greater than that of the constant air volume blower 400 for exhaust. It is preferable to operate the rotation speed of 300) larger than the rotation speed of the constant airflow blower 400 for exhaust. It is preferable to rotate the motor rotation speed of the constant air volume blower 300 for supply air 5 to 10% greater than the motor rotation speed of the constant air volume blower 400 for exhaust. The airflow amount of the constant airflow blower 300 for supplying air is greater than that of the constant airflow blower 400 for exhaust. Accordingly, the room is maintained in a positive pressure state.

After operating the constant air volume blower 300 for supply air and the constant air volume blower 400 for exhaust, respectively, the number of rotations of the constant air volume blower 300 for supply air is detected, and the rotation speed of the constant air volume blower 300 for supply air is set. A step (S2) of monitoring whether the area rotates is performed. The rotational speed of the constant airflow blower 300 for supply air can be known by sensing the rotational speed of the BLDC motor 7 constituting the constant airflow blower 300 for supply air. For example, it is preferable that the region of the set rotational speed of the constant airflow blower 300 for supplying air is 2670 to 2770 RPM. When the rotational speed of the constant airflow blower 300 for supply air is maintained in the range of 2670 to 2770 RPM, the set constant airflow is generated within an error range of about 10%.

When the rotational speed of the constant airflow blower 300 for supplying air rotates at a rotational speed greater than the set rotational speed region, a step (S3) of generating a notification for filter replacement proceeds. When the vent holes of the filter are gradually filled with foreign substances while maintaining the constant air volume, the rotation speed of the constant air flow blower 300 for supply is increased to maintain the constant air volume. It is judged that the holes are clogged more than the standard value, and the replacement time of the filter is notified.

4 is a flowchart illustrating a second embodiment of a method for notifying a filter replacement time of a total heat exchanger according to the present invention.

As shown in FIG. 4, the second embodiment of the method for notifying the filter replacement timing of the total heat exchanger is the first step (S11) of operating the constant air volume blower 300 for supply air and the constant air volume blower 400 for exhaust air, respectively. proceeds As the constant air volume blower 300 for supply air and the constant air volume blower 400 for exhaust are operated, respectively, as described in the first embodiment, outdoor air is filtered and supplied to the room, and the indoor air exchanges heat with the outdoor air. discharged outside.

When the constant air volume blower 300 for supply air and the constant air volume blower 400 for exhaust are operated, respectively, the airflow amount of the constant air volume blower 300 for supply air is greater than that of the constant air volume blower 400 for exhaust. It is preferable to operate the rotation speed of 300) larger than the rotation speed of the constant airflow blower 400 for exhaust. It is preferable to rotate the motor rotation speed of the constant air volume blower 300 for supply air 5 to 10% greater than the motor rotation speed of the constant air volume blower 400 for exhaust. The airflow amount of the constant airflow blower 300 for supplying air is greater than that of the constant airflow blower 400 for exhaust. Accordingly, the room is maintained in a positive pressure state.

After operating the constant air volume blower 300 for supply air and the constant air volume blower 400 for exhaust, respectively, the number of rotations of the constant air volume blower 300 for supply air is detected, and the rotation speed of the constant air volume blower 300 for supply air is set. A step (S12) of monitoring whether the area rotates is performed.

Pre-filter 510 constituting the filter unit 500 when the rotational speed of the constant airflow blower 300 for supply air is monitored while the rotational speed of the constant airflow blower 300 for supply air rotates at a rotational speed greater than the set rotational speed region. , a filter setting step (S13) of setting the replacement time of the medium filter 520, or the HEPA filter 530 is performed.

In the filter setting step (S13), the amount of air generated in the first reference rotational speed region of the constant airflow blower 300 for supplying air is referred to as the first airflow, and in the second reference rotational speed region smaller than the first reference rotational speed region. When the generated air volume is referred to as the second air volume, and the air volume generated in the third reference speed area smaller than the second reference speed area is referred to as the third air volume, the first reference speed area in the state where the first air volume is set When an abnormality is detected, a notification to replace the HEPA filter 530 is generated, and when abnormality is detected in the second reference rotational speed region in a state where the second air volume is set, a notification to replace the medium filter 520 is generated, and the third When the third reference rotation speed region or more is detected in the state where the air volume is set, a notification for replacing the pre-filter 510 is generated. For example, it is preferable that the first air volume is 200CMH, the second air volume is 150CMH, and the third air volume is 100CMH. In addition, it is preferable that the first reference rotation speed region is 2670 to 2770 RPM, the second reference rotation speed region is 2460 to 2560 RPM, and the third reference rotation speed region is 2100 to 2200 RPM.

That is, in a state in which the air volume of the constant air volume blower 300 for supply air is set to the first air volume of 200CMH, the motor rotational speed of the constant air volume blower 300 for supply air becomes 2670 to 2770 RPM or more, which is the first reference speed range. In a state where a replacement notification of the filter 530 is generated, and the air volume of the constant air volume blower 300 for supply air is set to 150CMH, which is the second air volume, the motor speed of the constant air volume blower 300 for supply air is the second reference speed range When the phosphorus is 2460~2560 RPM or more, a replacement notification of the medium filter 520 is generated, and the air volume of the constant air volume blower 300 for supply air is set to 100CMH, which is the third air volume. When the motor rotation speed is greater than 2100 to 2200 RPM, which is the second reference rotation speed range, a replacement notification of the pre-filter 510 is generated. The manager replaces the pre-filter 510 , the medium filter 520 , or the HEPA filter 530 when the replacement time is indicated by the notification unit 600 .

As such, in the second embodiment of the method for notifying the filter replacement timing of the total heat exchanger according to the present invention, when the constant airflow blower 300 for supply rotates at a rotation speed greater than or equal to the set rotation speed range, the filter setting step is performed and the filter setting is performed. The state of the pre-filter 510, the medium filter 520, and the HEPA filter 530 constituting the filter unit 500 while rotating the constant airflow blower 300 for supply air with the first, second, and third air volumes set in step The pre-filter 510, the medium filter 520, and the HEPA filter 530 are each used as experimental values because it informs the filter replacement time for each of the pre-filter 510, medium filter 520, and HEPA filter 530. It can be replaced at the optimal replacement time according to the

As described above, in the method of notifying the filter replacement timing of the total heat exchanger according to the present invention, when the constant airflow blower 300 for supplying air of the total heat exchanger supplies outdoor air to the room, outdoor air is filtered through the filter unit 500 As the air is continuously supplied into the room, fine dust and foreign substances mixed with the outdoor air are accumulated in the filter unit 500, which causes the filter unit 500 to be adhesively clogged, and the filter unit 500 is gradually clogged to show an appropriate function according to the experimental values. Since the replacement time of the filter unit 500 is notified to the manager at the time when the filter unit 500 cannot be replaced, the manager replaces the filter unit 500 at the optimum filter replacement time. Due to this, not only prevents overload of the constant air flow blower 300 for air supply by the filter unit 500, but also prevents waste of the filter and facilitates maintenance.

In addition, in the present invention, when the filter unit 500 includes the pre-filter 510 , the medium filter 520 , and the HEPA filter 530 , the pre-filter 510 and the medium filter are notified by an appropriate replacement time of each filter. 520 , it is possible to replace the HEPA filter 530 at an optimal time, thereby preventing wastage of the filter and maintaining the proper filtration performance of the filter unit 500 .

100; housing 200; heat exchange element
300; constant airflow blower 400 for supply air; Constant air volume blower for exhaust
500; filter unit 600; notification unit
700; control unit

Claims (4)

delete The first side plate, which is one side plate, is provided with an indoor air inlet and an indoor exhaust port, and the second side plate, which is the other side plate facing the first side plate, is provided with an outdoor air inlet and an outdoor exhaust port, and has an indoor exhaust port inside. a housing provided with an exhaust passage through which the indoor air is discharged to the outdoors by communicating with the outdoor exhaust port and an air supply passage through which outdoor air flows into the room by communicating the indoor air supply and the outdoor air supply therein; a heat exchange element mounted inside the housing to exchange heat between indoor air discharged through an exhaust passage and outdoor air flowing into an air supply passage; a constant airflow blower for supplying air provided in the air supply passage adjacent to the indoor air supply port to generate an inflow flow; a constant air volume blower for exhaust which is provided in the exhaust passage adjacent to the outdoor exhaust port to generate an exhaust flow; a filter unit provided in the air supply passage of the housing to filter outside air; a notification unit notifying the filter replacement time of the filter unit; and a control unit including a control that detects the rotation of the constant airflow blower for supply and the constant airflow blower for exhaust and generates a notification of the notification unit when the number of rotations is greater than or equal to a set value, wherein the constant airflow blower for supply and exhaust In the total heat exchanger comprising a pre-filter, a medium filter, and a HEPA filter, the constant air volume blower for each includes a BL DC motor and an impeller rotated by the BL DC motor,
operating the constant air volume blower for supply air and the constant air volume blower for exhaust, respectively;
monitoring whether the rotation speed of the constant airflow blower for supplying air rotates in a set rotational speed region by sensing the rotational speed of the constant airflow blower for supplying air;
A filter setting step of setting the replacement timing of the pre-filter, medium filter, or HEPA filter constituting the filter unit when the rotation speed of the constant airflow blower for supply air rotates at a rotation speed greater than the set rotation speed region;
The filter setting step is
The air volume generated in the first reference rotation speed region of the constant air volume blower for supplying air is referred to as the first air volume, and the air volume generated in the second reference rotation speed area smaller than the first reference rotation speed area is referred to as the second air volume, When an air volume generated in a third reference rotation speed region smaller than the second reference rotation speed region is referred to as a third air volume, when an abnormality is detected in the first reference rotation speed region in a state where the first air volume is set, the HEPA filter generates a notification to replace the medium filter, and generates a notification to replace the medium filter when an abnormality is detected in the second reference rotation speed region in the state where the second air volume is set, and the third standard in the state where the third air volume is set Filter replacement time notification method of a total heat exchanger, characterized in that when an abnormality is detected in the rotational speed range, a notification to replace the pre-filter is generated. The method according to claim 2, wherein the first, second, and third air volumes are 200CMH, 150CMH, and 100CMH, respectively, and the first, second, and third reference rotation speed ranges are 2670 to 2770 RPM, 2460 to 2560 RPM, and 2100 to 2200 RPM, respectively. Filter replacement time notification method of the total heat exchanger, characterized in that. 3. The method of claim 2, wherein the constant air flow rate blower for supplying air has a higher airflow rate than that of the exhaust constant air volume blower, and the rotation speed of the constant air flow rate blower for supply is greater than the rotation speed of the exhaust constant air volume blower. How to notify the filter replacement time of the total heat exchanger.

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