KR102506019B1 - Ventilator and the control method thereof - Google Patents

Abstract

The purpose of the present invention is to provide a ventilation device and a method for controlling the ventilation device that can minimize the static pressure loss of the blower by determining the cause of filter clogging and automatically eliminating the filter clogging state through a control method suitable for the cause. there is. The ventilation apparatus of the present invention for implementing this includes a filter provided on a flow path of air supplied to the room; a blower for sucking air supplied into the room; a filter clogging determining unit for determining the degree of clogging of the filter and the cause of the clogging; a humidity sensor for measuring the humidity of the air passing through the filter and providing the measured humidity to the filter blockage determining unit; and a drying unit for drying using air supplied to the filter when the cause of clogging of the filter is humidity.

Description

Ventilation device and control method of ventilation device {VENTILATOR AND THE CONTROL METHOD THEREOF}

The present invention relates to a ventilation device and a method for controlling the ventilation device, and more particularly, to a ventilation device capable of determining the cause of filter clogging and automatically removing the cause of filter clogging and a method for controlling the ventilation device.

In general homes and offices, cooling and heating devices are installed to perform indoor cooling and heating according to seasonal changes, and air conditioners perform cooling and heating by cooling and heating indoor air. , boilers, etc.

Indoors, such as general homes and offices, where such air conditioning and heating devices are installed are maintained in a sealed state to improve cooling and heating efficiency. Odor is generated or foreign substances such as dust float. Therefore, indoor air is ventilated at regular intervals to remove odors and dust from indoors. Ventilation is used to more quickly exhaust polluted indoor air to the outdoors and supply fresh outdoor air to the indoors while maintaining the indoor temperature. device is used

A filter for filtering foreign substances contained in the air is installed in such a ventilation device. When the ventilation device is used for a certain period of time or more, foreign substances accumulate in the filter, so it is necessary to periodically clean or replace the filter.

In general, the pre-filter is replaced at least once every 2-3 months, and the HEPA filter is replaced every 6 months to 1 year. Since the pre-filter, which filters relatively large dust, is clogged before the HEPA filter, which filters small dust, the pre-filter has a shorter cleaning cycle than the HEPA filter.

As a prior art capable of cleaning the dust accumulated in the filter as described above, Korean Patent Registration No. 10-0894362 has been disclosed.

However, the filter may be clogged by moisture particles in addition to being clogged by dust. In particular, when outdoor air contains a large amount of moisture, such as in the rainy season, when a ventilation device is operated to ventilate, the pores of the filter may be blocked by moisture particles while the outdoor air containing a large amount of moisture passes through the filter.

In this way, when the filter is clogged with moisture particles, there is a problem in that even if the blower is operated, a loss of static pressure occurs and the air volume of the blower decreases.

The present invention has been made to solve the above-mentioned problems, and a ventilation device capable of minimizing static pressure loss of a blower by determining the cause of filter clogging and automatically clearing the filter clogging state through a control method suitable for the cause, and Its purpose is to provide a control method for a ventilation system.

The present invention is to provide a ventilation device and a control method of the ventilation device that can prevent unnecessary alarms from occurring by resolving the filter clogging state through filter drying without generating a filter clogging alarm when the cause of filter clogging is determined to be humidity. It has a purpose.

Ventilator of the present invention for achieving the above object, a filter provided on the flow path of the air supplied to the room; a blower for sucking air supplied into the room; a filter clogging determining unit for determining the degree of clogging of the filter and the cause of the clogging; a humidity sensor for measuring the humidity of the air passing through the filter and providing the measured humidity to the filter blockage determining unit; and a drying unit for drying using air supplied to the filter when the cause of clogging of the filter is humidity.

The blower rotation speed sensor for detecting the rotation speed of the blower may be further included.

The filter clogging determination unit may determine the degree of clogging of the filter based on the number of rotations of the blower received from the rotation speed detection unit of the blower.

The drying unit may include a heat exchanger for dehumidifying air flowing toward the filter.

An alarm generating unit may be provided to generate an alarm when the cause of the clogging of the filter is a foreign substance.

The filter may be coupled to a total heat exchanger for total heat exchange when operating in a ventilation mode in which indoor air and outdoor air are exchanged.

At least one damper may be provided to allow indoor air to pass through the filter and operate in a clean dehumidifying mode for supplying the air passing through the filter to the indoor space.

The drying unit may be provided at a position to dehumidify the introduced indoor air and then supply it to the filter.

A control method of a ventilator of the present invention includes the steps of: a) determining the degree of clogging of a filter provided on a flow path of air supplied to a room; b) determining the cause of the clogging by measuring the humidity of the air passing through the filter when the degree of clogging of the filter corresponds to a set condition; c) drying the filter when the cause of filter clogging is humidity.

In step a), the degree of clogging of the filter may be determined by measuring the number of rotations of a blower for supplying air to the room.

In the step b), when the humidity of the air is equal to or greater than the set humidity, the cause of clogging of the filter may be determined as humidity.

In step b), when the humidity of the air is lower than the set humidity, it is determined that the cause of filter clogging is a foreign substance, and an alarm may be generated without proceeding with step c).

The step of drying the filter in step c) may be a step of sucking indoor air and passing the filter.

The step of drying the filter in step c) may be a step of operating in a clean dehumidification mode in which indoor air is sucked in and dehumidified, and the dehumidified air passes through the filter.

When the humidity of the air passing through the filter is lower than the set humidity by performing step c), the filter clogging degree determination in step a) is performed again, and the filter clogging degree is determined and the set condition is satisfied. An alarm may be generated without performing the humidity measurement step of step b).

The step of drying the filter in step c) may be a step of operating in a dehumidifying ventilation mode in which outdoor air is dehumidified and introduced into the room.

According to the present invention, the static pressure loss of the blower can be minimized by determining the cause of filter clogging and automatically eliminating the clogged filter through a control method suitable for the cause.

In addition, when the cause of filter clogging is determined to be humidity, it is possible to prevent unnecessary alarms from occurring and to prevent users from experiencing discomfort due to alarms by resolving the filter clogging state through filter drying without generating a filter clogging alarm. there is.

1 is a plan schematic view of a ventilator according to the present invention.
2 is a schematic side view of a ventilator according to the present invention.
3 is a view showing a control configuration of a ventilator according to the present invention.
4 is a view showing air flow when the ventilation device according to the present invention operates in a ventilation mode.
5 is a view showing air flow when the ventilation device according to the present invention operates in a clean dehumidification mode.
6 is a flowchart showing a method for controlling a ventilator according to the present invention.

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

The configuration of the ventilator 1 according to the present invention will be described with reference to FIGS. 1 to 3 .

The ventilator 1 has a first exhaust chamber 10 into which indoor air is introduced and a second exhaust chamber which discharges indoor air to the outdoors via the first exhaust chamber 10, based on the heat exchange mode. The chamber 20, the first air supply chamber 30 into which outdoor air is introduced, the second air supply chamber 40 that supplies outdoor air via the first air supply chamber 30 to the room, the first exhaust chamber ( A total heat exchanger 50 in which heat is exchanged between indoor air flowing from 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, and the first air supply chamber 50 It is provided on one side of the total heat exchanger 50 facing the first air supply chamber 30 and includes a filter 60 for filtering foreign substances contained in the air flowing into the total heat exchanger 50.

In addition, a damper 70 may be provided in the bulkhead 80 partitioning the space between the first exhaust chamber 10 and the first air supply chamber 30 . When the damper 70 is opened, the first exhaust chamber 10 and the first air supply chamber 30 communicate with each other.

In addition, as shown in FIG. 2, the bottom of the first exhaust chamber 10, the second exhaust chamber 20, the first air supply chamber 30, the second air supply chamber 40 and the total heat exchanger 50 ( A bypass passage 82 may be formed with 81 therebetween. In this case, at least one damper (13,33) is provided on the bottom (81) of the first exhaust chamber (10) and the first air supply chamber (30), and the damper (13,33) is opened to The chamber 10 and the first air supply chamber 30 can be communicated with each other.

In addition, when indoor air is exhausted to the outdoors without passing through the total heat exchanger 50, at least one damper is provided so that the first exhaust chamber 10 and the second exhaust chamber 20 communicate through the bypass passage 82 It could be.

An indoor air inlet 11 through which indoor air flows in is provided on the indoor side of the first exhaust chamber 10, 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. An outdoor air inlet 31 through which outdoor air is introduced is provided on the outdoor side of the first air supply chamber 30, and an outdoor air inlet 31 through which outdoor air is discharged to the indoor side is provided on the indoor side of the second air supply chamber 40. An outlet 41 is provided.

At least two dampers may be provided in the indoor air inlet 11, the indoor air outlet 21, the outdoor air inlet 31, and the outdoor air outlet 41 to introduce or discharge indoor air and outdoor air. .

An exhaust blower 22 for forcibly sucking indoor air to the outside is provided in the second exhaust chamber 20, and an air supply blower 42 for forcibly sucking outdoor air to the indoor side is provided in the second air supply chamber 40. is provided

The total heat exchanger 50 has a structure in which a flow path through which indoor air flows and a flow path through which outdoor air flow are alternately formed therein so that heat can be exchanged between indoor air and outdoor air.

One side of the total heat exchanger 50 facing the first air supply chamber 30 is provided with a filter 60 for filtering foreign substances included in supplied outdoor air or recirculated indoor air. The filter 60 may be a HEPA filter, a pre-filter, a medium filter, a deodorizing filter, or the like. In this case, the HEPA filter is located on the side of the total heat exchanger 50, and the pre-filter is located on the side of the first air supply chamber 30, but has a stacked structure.

The second exhaust chamber 20, the first air supply chamber 30, and the second air supply chamber 40 are provided with heat exchangers 91, 92, 93, and 94 constituting the evaporator or condenser of the heat pump 90. has been The heat pump 90 includes a compressor, a four-way valve, an expansion valve, a liquid separator, a solenoid valve, and the like, and the heat exchangers 91, 92, 93, and 94 function as evaporators through compression and expansion processes of refrigerant. It cools the air or acts as a condenser to heat the air.

The ventilator 1 includes a ventilation mode in which indoor air and outdoor air are exchanged, a heating ventilation mode or a cooling ventilation mode in which air supplied to the room is heated or cooled in the ventilation mode, and a ventilation mode supplied to the room in the ventilation mode. A dehumidification ventilation mode that dehumidifies air, a clean dehumidification mode that dehumidifies and filters indoor air and then supplies it to the room, a heat exchange mode in which heat is exchanged between the exhausted indoor air and the supplied outdoor air, and the exhausted indoor air is a total heat exchanger (50) A mode setting unit (not shown) for selecting a bypass mode in which exhaust is exhausted via the bypass passage 82 without passing through the ventilator 1 according to the operation mode set in the mode setting unit It includes a control unit 100 for controlling.

The first exhaust chamber 10 is provided with a first temperature sensor 15 and a first humidity sensor 16 for measuring the temperature and humidity of indoor air flowing into the first exhaust chamber 10, respectively. The first air supply chamber 30 is provided with a second temperature sensor 35 and a second humidity sensor 36 for measuring the temperature and humidity of outdoor air flowing into the first air supply chamber 30, respectively.

A blower rotational speed detection unit 45 for detecting the rotational speed of the air supply blower 42 is provided. As the clogging of the filter 60 progresses, the rotational speed detected by the blower rotational speed sensor 45 increases, so the degree of clogging of the filter 60 can be determined from the rotational speed of the air supply blower 42. can

The control unit 100 includes a filter clogging determination unit 110 for determining the degree of clogging of the filter 60 and the cause of the clogging, and for controlling the driving of the air supply blower 42 and the exhaust blower 22 It includes a blower driving unit 120, a heat pump driving unit 130 for controlling driving of the heat pump 90, and a damper driving unit 140 for controlling driving of the damper.

The filter clogging determination unit 110 determines the degree of clogging of the filter 60 from the rotational speed of the air supply blower 42 detected by the blower rotational speed detection unit 45, and based on the determination result, the second The cause of clogging of the filter 60 may be determined from the humidity of the air passing through the filter 60 detected by the humidity sensor 36 .

When the cause of clogging of the filter 60 is humidity, clogging of the filter 60 can be eliminated only by performing a process of drying the filter 60 . If the cause of clogging of the filter 60 is not humidity but a foreign substance such as dust, the filter 60 must be cleaned or replaced. Therefore, the method for resolving the clogging varies depending on the cause of clogging of the filter 60 .

When it is determined that the cause of clogging of the filter 60 is humidity, a drying unit for drying the filter 60 is provided. The drying unit may include at least one heat exchanger 93 or 94 to dehumidify air flowing toward the filter 60 . In order to dry the filter 60 using the drying unit, the control unit 100 dehumidifies outdoor air introduced into the first air supply chamber 30 in the ventilation mode and then passes the filter 60 through the filter 60. can be dried. Of course, the filter 60 may be dried by passing the filter 60 after heating the outdoor air according to the condition of the outdoor air.

In addition, in the clean dehumidification mode, the filter 60 can be dried by allowing the indoor air introduced into the first exhaust chamber 10 to flow into the first air supply chamber 30 for dehumidification and then pass through the filter 60. .

When the heat pump 90 is provided, the heat exchangers 93 and 94 function as condensers to heat the air flowing toward the filter 60, thereby drying the filter 60.

An alarm generating unit 200 generating an alarm when the cause of clogging of the filter 60 is a foreign substance is provided. In this case, the user can eliminate the clogging of the filter 60 by removing and cleaning or replacing the filter 60 .

A method of controlling a ventilator according to the present invention will be described with reference to FIGS. 4 to 6 .

In step S11, the ventilator 1 is operated in a ventilating mode. When operated in the ventilation mode, as shown in FIG. 4, the exhaust blower 22 is operated and the indoor air is blown outdoors through the first exhaust chamber 10, the total heat exchanger 50, and the second exhaust chamber 20. and the air supply blower (42) is operated so that outdoor air is introduced into the room through the first air supply chamber (30), the total heat exchanger (50), and the second air supply chamber (40). When the ventilation mode is operating, the heat pump 90 is operated so that the heat exchanger (93 or 94) functions as an evaporator to dehumidify the outdoor air flowing into the first air supply chamber (30). Therefore, it is possible to prevent an increase in clogging of the filter 60. When the ventilation mode is operated, heat is exchanged between indoor air and outdoor air in the total heat exchanger (50).

In step S12, the rotational speed of the air supply blower 42 is detected by the blower rotational speed detector 45 during operation in the ventilation mode, and it is determined whether the detected rotational speed is higher than the set rotational speed. The set number of rotations may be appropriately set to a number of rotations determined that the degree of clogging of the filter 60 affects the static pressure loss of the air supply blower 42 . As a result of the determination, if the number of revolutions of the air supply blower 42 is higher than the set number of revolutions, it is determined that the degree of clogging of the filter 60 affects the static pressure loss and proceeds to step S13, otherwise proceeds to step S18.

In step S13, the humidity of the outdoor air (OA) is measured by the second humidity sensor 36, and it is determined whether the measured humidity is equal to or greater than a set humidity. When the measured humidity is greater than or equal to the set humidity, it may be determined that the filter 60 is clogged due to the humidity, and thus the number of revolutions of the air supply blower 42 is higher than the set number of revolutions. If the measured humidity is not equal to or greater than the set humidity, it can be determined that the filter 60 is not clogged due to the humidity, but clogged by a foreign substance such as dust. As a result of the determination, if the humidity is equal to or greater than the set humidity, the process proceeds to step S15, otherwise, the process proceeds to step S14.

In step S14, it is determined that the filter 60 is clogged by a foreign substance, and the alarm generating unit 200 generates a filter inspection alarm. When the alarm occurs, the user clears the clogging of the filter 60 by cleaning or replacing the filter 60 .

In step S15, the ventilator 1 is operated in a clean dehumidifying mode. Since the filter 60 is clogged due to the operation of the ventilation mode in a high humidity state of outdoor air, it is difficult to dry the filter 60 using outdoor air. Therefore, the filter 60 is dried using indoor air.

When operated in the clean dehumidification mode, as shown in FIG. 5, the damper 70 is open, the exhaust blower 22 is in a stopped state, and the damper (not shown) provided at the indoor air outlet 21 is closed. Therefore, the indoor air is not discharged to the outdoors through the indoor air outlet 21. In addition, since the damper provided at the outdoor air inlet 31 is also closed, outdoor air does not flow in through the outdoor air inlet 31 . In this state, when the air supply blower 22 is operated, indoor air flows into the first exhaust chamber 10 and then into the first air supply chamber 30 through the open damper 70 . The indoor air introduced into the first air supply chamber 30 is dehumidified by operating the heat pump 90 so that the heat exchanger 93 or 94 functions as an evaporator. The dehumidified room air dries the filter 60 while passing through the filter 60, and the air passing through the filter 60 is introduced into the room again through the second air supply chamber 40. In this process, the foreign matter contained in the indoor air is filtered by the filter 60, and the indoor air is purified.

In step S16, the humidity of the indoor air (RA) flowing into the first exhaust chamber 10 is measured by the first humidity sensor 16, and it is determined whether the measured humidity is lower than the set humidity. As a result of the determination, if the measured humidity is lower than the set humidity, it is determined that dehumidification has been performed and the process proceeds to step S17, otherwise the current operating state is maintained.

In step S17, the rotational speed of the air supply blower 42 is measured, and it is determined whether the measured rotational speed is higher than the set rotational speed. As a result of the determination, if the measured number of revolutions is higher than the set number of revolutions, it is determined that the blockage is caused by a foreign substance, and the filter inspection alarm is generated by proceeding directly to step S14 without going through the humidity check step of step S13.

The filter 60 drying mode as described above may be performed by a user's selection or may be automatically performed according to a cycle preset in the ventilator 1.

Through the above process, it is possible to minimize the static pressure loss of the blower by determining the cause of clogging of the filter 60 and automatically clearing the clogged state of the filter 60 through a control method suitable for the cause. In addition, when it is determined that the cause of clogging of the filter 60 is humidity, unnecessary alarm generation is prevented and an alarm is generated by resolving the clogging state of the filter 60 through drying of the filter 60 without generating a clogging alarm of the filter 60. As a result, it is possible to prevent the user from feeling uncomfortable.

As described above, the present invention has been described in detail with preferred embodiments, but the present invention is not limited to the above-described embodiments, and various modifications are made within the scope of the claims and the detailed description of the invention and the accompanying drawings. It is possible to carry out by doing, and this also belongs to the present invention.

10: first exhaust chamber 15: first temperature sensor
16: first humidity sensor 20: second exhaust chamber
22: exhaust blower 30: first air supply room
35: second temperature sensor 36: second humidity sensor
40: second air supply room 42: air supply blower
60: filter 70: damper
90: heat pump 100: control unit
110: filter clogging determination unit 120: blower driving unit
130: heat pump driving unit 140: damper driving unit
200: alarm generating unit

Claims (14)

A filter provided on a flow path of air supplied to the room;
a blower for sucking air supplied into the room;
a filter clogging determination unit for determining the degree of clogging of the filter and the cause of the clogging of the filter;
a humidity sensor for measuring the humidity of the air passing through the filter and providing the measured humidity to the filter blockage determining unit;
a drying unit for drying the filter using air supplied to the filter when the degree of clogging of the filter determined by the filter clogging determination unit corresponds to a set condition and the cause of clogging of the filter is humidity;
Ventilation device containing According to claim 1,
Further comprising a blower rotational speed sensor for detecting the rotational speed of the blower;
The filter clogging determination unit determines the degree of clogging of the filter from the rotational speed of the blower received from the rotational speed detection unit of the blower. According to claim 1,
The drying unit is a ventilation device, characterized in that consisting of a heat exchanger for dehumidifying the air flowing toward the filter According to claim 1,
A ventilation device characterized in that an alarm generating unit for generating an alarm when the cause of the filter clogging is a foreign substance According to claim 1,
The filter is a ventilation device, characterized in that coupled to a total heat exchanger for total heat exchange during operation of a ventilation mode in which indoor air and outdoor air are exchanged According to claim 1,
at least one damper is provided to allow the indoor air to pass through the filter and to operate in a clean dehumidification mode supplying the air passing through the filter to the indoor space;
The ventilation device characterized in that the drying unit is provided at a position to dehumidify the inflow indoor air and then supply it to the filter. a) determining the degree of clogging of a filter provided on a flow path of air supplied to the room;
b) determining the cause of the clogging by measuring the humidity of the air passing through the filter when the degree of clogging of the filter corresponds to a set condition;
c) drying the filter when the cause of filter clogging is humidity;
Ventilation device control method comprising a According to claim 7,
In the step a), the degree of clogging of the filter is determined by measuring the number of rotations of a blower for supplying air to the room. According to claim 8,
In the step b), when the humidity of the air is equal to or greater than the set humidity, the cause of clogging of the filter is determined as humidity. According to claim 8,
In the step b), when the humidity of the air is lower than the set humidity, the cause of the clogging of the filter is determined as a foreign substance, and an alarm is generated without proceeding with the step c). According to claim 7,
The step of drying the filter in step c) is a step of sucking in indoor air and operating it to pass through the filter. According to claim 11,
The step of drying the filter in step c) is a step of operating in a clean dehumidification mode in which indoor air is sucked in and dehumidified, and the dehumidified air passes through the filter. According to claim 11,
When the humidity of the air passing through the filter is lower than the set humidity by performing step c), the filter clogging degree determination in step a) is performed again, and the filter clogging degree is determined and the set condition is satisfied. Control method of a ventilator, characterized in that for generating an alarm without performing the humidity measuring step of step b) According to claim 7,
The step of drying the filter in step c) is a step of operating in a dehumidifying ventilation mode in which outdoor air is dehumidified and then introduced into the room.

Images