KR102264921B1 - Dust collection module and dust collection module assembly including the same - Google Patents

Abstract

The present invention relates to a dust collection module and a dust collection module assembly including the same, which is able to be installed in an air conditioning system to generate an airflow of an axial flow, to improve air-conditioning efficiency, and reduce dust concentration in the air. In accordance with the present invention, the dust collection module comprises an axial flow generation module and a pipe-shaped nanofiber filter. The axial flow generation module absorbs the air through an entrance, and emits an airflow of the axial flow through an exit on the opposite side to the entrance. In addition, the nanofiber filter has an inner space in which the axial flow generation module is built with a certain gap, collects and remove pollutants included in the air absorbed from outside by the driving of the axial flow generation module by using a surface filtering method, and provides the air, from which the pollutants are removed, to the entrance of the axial flow generation module. The present invention provides a dust collection module assembly which includes a plurality of dust collection modules placed by being accumulated.

Description

Dust collection module and dust collection module assembly including the same

The present invention relates to an air conditioning system, and more particularly, to a dust collection module installed in the air conditioning system to generate an axial air flow to improve air conditioning efficiency and reduce dust concentration in a space, and to a dust collection module assembly including the same.

The air conditioning system forcibly circulates indoor air, discharges indoor polluted air to the outdoors, and supplies fresh outdoor air to the interior, and is mainly installed in buildings such as buildings or houses having a certain space.

Such an air conditioning system is composed of a ventilation device for supplying outdoor air to the room and exhausting the indoor air to the outside, and a duct for communicating each room in the ventilation device.

When the air conditioning system is used for a long time, bacteria such as dust, bacteria, and viruses in the air enter the duct and live inside the duct. Bacteria inside can be fed into the room together.

In order to solve this problem, a filter may be installed in the air conditioning system to filter out pollutants contained in the air, such as odors, volatile organic compounds (VOCs), cigarette smoke, fine dust, and the like.

When a filter is additionally installed in the existing air conditioning system, the wind pressure of the air supplied from the air conditioning system is reduced due to the filter, and thus the air is not circulated stably through the duct, thereby reducing the air conditioning efficiency.

Therefore, when a filter is installed in the air conditioning system, there is a problem in that it must be replaced with a ventilation device having a larger capacity than the existing ventilation device in consideration of the reduction in wind pressure due to the filter. Moreover, if the target to be removed with the filter is ultrafine dust, it should be replaced with a larger capacity ventilation device.

As such, in order to install a ventilation device with a larger capacity than the existing one, an installation space is required accordingly. However, if the installation space in the air conditioning room where the ventilation device is installed is not sufficient, there may be a problem that the ventilation device cannot be replaced with a ventilation device with a large capacity fundamentally.

Unexamined Patent Publication No. 2018-0100226 (2018.09.07.)

Accordingly, it is an object of the present invention to provide a dust collecting module capable of implementing stable air conditioning efficiency by minimizing a decrease in wind pressure due to a filter and a dust collecting module assembly including the same.

Another object of the present invention is to provide a dust collecting module capable of additionally installing a filter without replacing an existing ventilation device, and a dust collecting module assembly including the same.

Another object of the present invention is to provide a dust collecting module and a dust collecting module assembly including the same for reducing the dust concentration in a space while improving air conditioning efficiency by generating an axial air flow.

Another object of the present invention is to provide a dust collecting module capable of generating an airflow over a long distance to expand a shared area per unit, and a dust collecting module assembly including the same.

Another object of the present invention is to provide a dust collecting module for maintaining a constant velocity of an airflow and a dust collecting module assembly including the same.

Another object of the present invention is to provide a dust collecting module capable of improving the dust collection efficiency of ultrafine dust, easily dedusting the collected contaminants and reusing the filter, and a dust collecting module assembly including the same.

In order to achieve the above object, the present invention is a hollow axial flow generating module for sucking air through an inlet and discharging an axial airflow to an outlet opposite the inlet; and an internal space in which the axial flow generating module is built with a certain clearance, and the contaminants contained in the air sucked from the outside by driving the axial flow generating module are collected and removed by surface filtration, and the contaminants are removed It provides a dust collection module comprising a; a tubular nanofiber filter that provides the exhausted air to the inlet of the axial flow generating module.

The dust collecting module according to the present invention, the outlet side of the axial flow generating module is fixed, one end of the nanofiber filter corresponding to the outlet is fixed, the flange is formed with a through hole to communicate with the outlet; further includes.

The axial flow generating module may include: a motor having a drive shaft protruding toward the inlet; a fan coupled to the drive shaft and having a plurality of blades; a fixed-wing case coupled to an outer circumferential surface of the motor and having a plurality of fixed blades disposed to face a direction opposite to a wing direction of the fan; an air inlet pipe coupled to one side of the fixed wing case to which the fan is coupled and having the inlet through which air passing through the nanofiber filter is introduced; And one side is coupled to the other side of the fixed-wing case and the other side is fixedly installed on the flange, and the air introduced into the air inlet pipe passes through the fan and the fixed-wing case, and the air having the outlet is changed to an axial flow and discharged. exhaust pipe; includes.

The nanofiber filter, with respect to the flange, is longer than the length of the axial flow generating module, and the other side opposite to one side coupled to the flange is formed as an open part.

The dust collecting module according to the present invention further includes a diaphragm for opening and closing the inflow of air through the opening of the nanofiber filter.

When the axial flow generating module is driven in a state in which the diaphragm is opened, air is introduced into the nanofiber filter through the diaphragm and is directly supplied to the axial flow generating module.

When the axial flow generating module is driven in a state in which the diaphragm is closed, air from which contaminants are removed is supplied to the axial flow generating module through the outer surface of the nanofiber filter.

The axial flow generating module may further include a sound absorbing material built in each of the air inlet pipe or the air outlet pipe.

The dust collecting module according to the present invention includes: a nozzle installed in communication with the through hole of the flange to guide the external discharge of the axial flow through the outlet of the air discharge pipe; and a compressed air supplier for supplying compressed air to the inner space of the nanofiber filter to dedust the contaminants collected on the surface of the nanofiber filter.

The folding module according to the present invention may further include a differential pressure sensor installed on the nanofiber filter to detect a differential pressure applied to the nanofiber filter.

Control the speed of the axial flow emitted through the axial flow generating module by varying the output of the motor and the rotation speed of the fan according to the differential pressure detected by the differential pressure sensor, or the exhaustion or replacement timing of the nanofiber filter information can be provided.

The present invention also provides a dust collecting module assembly including a plurality of the dust collecting modules stacked and arranged in an M×N matrix (at least one of M and N being a natural number equal to or greater than 2).

And the plurality of dust collecting modules, respectively, the outlet side of the axial flow generating module is fixed, one end of the nanofiber filter corresponding to the outlet is fixed, and includes a flange formed with a through hole to communicate with the outlet. The plurality of dust collecting modules are stacked and arranged via the flange.

Since the dust collecting module according to the present invention has a structure in which an axial flow generating module is built inside the nanofiber filter, it is possible to realize stable air conditioning efficiency by minimizing the reduction in wind pressure due to the filter. That is, since the dust collecting module according to the present invention generates an axial airflow, when the dust collecting module according to the present invention is applied to an air conditioning system, the existing ventilation device can be used as it is.

Since the dust collecting module according to the present invention has a structure in which the axial flow generating module is built-in inside the nanofiber filter, it can be manufactured in a compact size. Accordingly, it is possible to minimize the problem of insufficient installation space due to the installation of the dust collecting module according to the present invention in the air conditioning room.

The dust collecting module according to the present invention can reduce the dust concentration in the space while improving the air conditioning efficiency by generating an axial air flow. That is, the dust collecting module can efficiently collect even ultrafine dust contained in the air by allowing the air sucked through the axial flow generating module to pass through the surface filtration nanofiber filter. Since the air filtered through the nanofiber filter is discharged to the outside as an axial flow by the axial flow generating module, purified air can be sent far away.

Due to this, the dust collecting module according to the present invention can expand the shared area per unit by generating an airflow over a long distance.

The dust collection module according to the present invention varies the output of the motor and the rotational speed of the fan provided in the axial flow generating module based on the pressure applied to the nanofiber filter, thereby maintaining the airflow speed to keep the air conditioning efficiency and dust collection efficiency constant. can keep

In the dust collection module according to the present invention, since the collected contaminants are present on the surface of the nanofiber filter, it is possible to shake off the contaminants present on the surface of the nanofiber filter and reuse it through the input of compressed air into the nanofiber filter. .

The dust collection module according to the present invention may provide the user with information on the time of exhaustion and replacement time based on the pressure applied to the nanofiber filter.

The dust collecting module according to the present invention can maintain a comfortable place in which the dust collecting module is installed through environmental information collected from the surrounding environment sensor and interlocking operation with other air conditioning equipment.

The dust collecting module according to the present invention may be installed to replace the filter in the air conditioning room, or may be installed by connecting between duct pipes.

In addition, the dust collecting module according to the present invention can effectively perform air circulation and dust collection for the installation site by arranging an appropriate number according to the capacity of the air conditioning system and driving them to be interlocked with each other. In this case, according to the capacity or installation space of the air conditioning system, the dust collecting module may be installed as a dust collecting module assembly arranged in an M×N matrix (at least one of M and N being a natural number equal to or greater than 2).

1 is a perspective view showing a dust collecting module according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along line 2-2 of FIG. 1 .
3 is an air flow chart according to the dust collection of the dust collection module of FIG.
4 is an air flow chart according to the air circulation of the dust collecting module of FIG.
5 is a view showing a dust collecting module assembly including a dust collecting module according to an embodiment of the present invention.

In the following description, only parts necessary for understanding the embodiments of the present invention will be described, and it should be noted that descriptions of other parts will be omitted without departing from the gist of the present invention.

The terms or words used in the present specification and claims described below should not be construed as being limited to their ordinary or dictionary meanings, and the inventors have appropriate concepts of terms in order to best describe their inventions. It should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined in Accordingly, the embodiments described in this specification and the configurations shown in the drawings are only preferred embodiments of the present invention, and do not represent all of the technical spirit of the present invention, so various equivalents that can be substituted for them at the time of the present application It should be understood that there may be variations and variations.

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

[Dust collection module]

1 is a perspective view showing a dust collecting module according to an embodiment of the present invention. And FIG. 2 is a cross-sectional view taken along line 2-2 of FIG. 1 .

1 and 2 , the dust collecting module 100 according to the present embodiment is an air purification device for an air conditioning system that generates an axial air flow to improve air conditioning efficiency and reduce dust concentration in a space. The dust collection module 100 according to this embodiment includes a hollow axial flow generating module 10 and a tubular nanofiber filter 60 . The axial flow generating module 10 draws in air through the inlet 22 and discharges the axial airflow to the outlet 24 opposite the inlet 22 . And the nanofiber filter 60 has an internal space 61 in which the axial flow generating module 10 is built with a certain clearance, and pollutants contained in the air sucked from the outside by the driving of the axial flow generating module 10 is removed by collecting dust by a surface filtration method, and air from which contaminants are removed is provided to the inlet 22 of the axial flow generating module 10 . In addition, the dust collecting module 100 according to the present embodiment may further include a flange 50 , an aperture 65 , a nozzle, a differential pressure sensor 70 , and a compressed air supply 80 .

As described above, since the dust collection module 100 according to the present embodiment has a structure in which the axial flow generating module 10 is built in the nanofiber filter 60, it can be manufactured in a compact size.

Here, the axial flow generating module 10 is a device that sucks air to generate an axial flow and sends the sucked air far away. The air sucked in and discharged by the axial flow generating module 10 may be external air itself or air (purified air) from which contaminants are removed by the nanofiber filter 60 .

The axial flow generating module 10 includes a motor 11 , a fan 14 , a fixed wing case 19 , an air inlet pipe 21 , and an air outlet pipe 23 . The motor 11 has a drive shaft 13 protruding toward the inlet 22 . The fan 14 is coupled to the drive shaft 13 and has a plurality of blades. The fixed blade case 19 is coupled to the outer peripheral surface of the motor 11 and includes a plurality of fixed blades 17 that are opposite to the wing direction of the fan 14 . The air inlet pipe 21 is coupled to one side of the fixed wing case 19 to which the fan 14 is coupled, so that air passing through the nanofiber filter 60 is introduced. And the air discharge pipe 23 is coupled to the other side of the fixed wing case 19, the air introduced into the air inlet pipe 21 passes through the fan 14 and the fixed wing case 19 to change into an axial flow and discharge.

The motor 11 includes a motor body 12 and a drive shaft 13 protruding from the motor body 12 toward the air inlet pipe 21 . The motor 11 may maintain a constant speed of the axial flow emitted through the axial flow generating module 10 by varying the output and the number of rotations. In order to compensate for the pressure loss according to the dust deposition degree of the nanofiber filter 60 , the motor 11 may generate an exhausted axial flow of a constant air amount by varying the output and the number of rotations. For example, as the motor 11, a BLDC motor capable of varying the output from 80W to 200W and the number of rotations from 3,000rpm to 4,800rpm may be used.

The fan 14 is coupled to the drive shaft 13 of the motor 11 , and generates an air flow from the air inlet pipe 21 to the air outlet pipe 23 when the motor 11 is driven. The diameter of the fan 14 is larger than the outer diameter of the motor 11 so that air can move toward the air discharge pipe 23 through the motor 11 by the driving of the fan 14 .

The fixed wing case 19 is coupled to and fixed to the motor body 12 . The fixed blade 17 is disposed to face the direction of the blade of the fan 14 in the opposite direction, and changes the spiral airflow passing through the fan 14 to an axial flow and sends it to the air discharge pipe 23 . A metal material having good heat dissipation may be used as a material of the fixed wing case 19 .

At this time, since the airflow generated by the rotation of the fan 14 according to the driving of the motor 11 passes through the motor body 12 through the fixed wing case 19, the heat generated according to the driving of the motor 11 is It is effectively discharged to the outside by the airflow passing through the fixed wing case 19 and the motor body 12 . Therefore, it is possible to extend the life of the motor 11 and exhibit stable performance of the motor 11 by the natural heat dissipation effect.

The air inlet pipe 21 is coupled to one side of the fixed wing case 19 where the fan 14 is located.

And the air outlet pipe 23 is coupled to the other side of the fixed wing case 19 opposite to the side to which the air inlet pipe 21 is coupled.

At this time, the air inlet pipe 21 and the air outlet pipe 23 are coupled in the same axial direction around the fixed wing case 19 to stably move the air introduced into the air inlet pipe 21 toward the air outlet pipe 23 . . In order for air to move stably through the air inlet tube 21 and the air outlet tube 23 , the air inlet tube 21 and the air outlet tube 23 are formed in a tube shape having the same inner diameter.

The air inlet pipe 21 is used as the inlet 22 of the axial flow generating module 10 through which air is introduced at the opposite side to the side coupled to the fixed wing case 19 . The air discharge pipe 23 is used as the outlet 24 of the axial flow generating module 10 through which the axial flow is discharged to the opposite side to the side coupled to the fixed wing case 19 .

The axial flow generating module 10 may further include a sound absorbing material 25 . The sound absorbing material 25 is respectively built in the air inlet pipe 21 or the air outlet pipe 23 to reduce noise generated according to the operation of the motor 11 , the fan 14 , and the fixed wing case 19 .

The flange 50 is a metal plate to which the outlet 33 side of the axial flow generating module 10 is fixed, and one end of the nanofiber filter 60 corresponding to the outlet 33 is fixed, and penetrates in communication with the outlet 33 . A hole 61 is formed. One end of the air discharge pipe 22 and the nanofiber filter 60 is blocked by the flange 50 . The axial flow is discharged through the through hole 61 .

The inner space 61 of the nanofiber filter 60 is formed in the form of a tube having a predetermined inner diameter. In order to maintain a constant gap between the nanofiber filter 60 and the axial flow generating module 10 , the axial flow generating module 10 is inserted into the inner space 61 of the nanofiber filter 60 . That is, the axial flow generating module 10 is inserted into the center of the axial direction of the inner space 61 of the nanofiber filter 60 .

The nanofiber filter 60 includes a tubular filter body 62 and a protective net 64 for protecting the inner and outer peripheral surfaces and both ends of the filter body 62 . The filter body 62 is a surface filtration filter that prevents deep deposition of fine dust by depositing polymer fibers with a diameter of 80-100 nm on the filter surface in a microfiber network structure, and has a tube shape with both sides open. The filter body 62 is manufactured by folding a sheet shape in a zig-zag shape and then rolling it in a penetrating shape. In order to maintain the shape of the tubular rolled filter body 62, a fixed ring is formed by applying a polymer resin in a ring shape at regular intervals on the outer circumferential surface in a direction perpendicular to the tubular rolled axial direction.

The protective net 64 allows the filter body 62 rolled in the form of a tube to maintain its shape. The protective net 64 may be made of a polymer resin or a metal material capable of providing rigidity to the filter body 62 .

Since the nanofiber filter 60 collects dust only on the surface, it can be reused after exhaustion. For example, as the nanofiber filter 60, Donaldson's nanofiber filter may be used.

The nanofiber filter 60 has a dust collection efficiency of more than 99.9% for ultrafine dust, the differential pressure is less than 40mmAq, and the pressure loss is small. Do.

During dust collection, the air that has passed through the nanofiber filter 60 moves toward the air inlet pipe 21 through the space between the axial flow generating module 10 and the nanofiber filter 60 . The nanofiber filter 60 is longer than the length of the axial flow generating module 10 with respect to the flange 50 , and the other side opposite to one side coupled to the flange 50 is formed as an opening 63 .

The reason for forming the nanofiber filter 60 longer than the axial flow generating module 10 is to allow the air purified by the nanofiber filter 60 to enter stably toward the inlet 22 of the air inlet pipe 21. it is for That is, the air purified while passing through the surface of the nanofiber filter 60 goes along the space between the nanofiber filter 60 and the axial flow generating module 10 to one end where the inlet 22 of the air inlet pipe 21 is formed. will move By forming the nanofiber filter 60 longer than the axial flow generating module 10 , a space is provided between the nanofiber filter 60 and one end of the air inlet pipe 21 . This is because the air, which has moved to one end of the air inlet tube 21 through the space, rotates in the opposite direction and can be guided to stably enter the inlet 22 of the air inlet tube 21 .

The diaphragm 65 is installed in the opening 63 of the nanofiber filter 60 to open and close the inflow of air through the opening 63 .

When dust collection is performed, as shown in FIG. 3 , the axial flow generating module 10 is driven in a state in which the diaphragm 65 is closed. When the axial flow generating module 10 is driven in the closed state of the diaphragm 65 , external air is sucked through the outer surface of the nanofiber filter 60 . The sucked air is supplied to the axial flow generating module 10 in a state in which contaminants are removed through the outer surface of the nanofiber filter 60 . Here, FIG. 3 is an air flow diagram according to dust collection of the dust collecting module 100 of FIG. 2 .

At this time, the air purified by passing through the nanofiber filter 60 moves toward the stop 65 through the space between the nanofiber filter 60 and the air inlet pipe 21 .

The purified air that has moved toward the diaphragm 65 is reversely rotated on the diaphragm 65 and sucked into the inlet 22 of the air inlet pipe 21 .

And the axial flow generating module 10 converts the purified air introduced into the inlet 22 of the air inlet pipe 21 into an axial flow and discharges it to the outside through the air outlet pipe 23 .

When air is circulated without dust collection, as shown in FIG. 4 , the axial flow generating module 10 is driven in an open state of the diaphragm 65 . That is, air is introduced into the interior through the opening 63 of the nanofiber filter 60 through the open diaphragm 65 and is directly supplied to the axial flow generating module 10 . When the diaphragm 65 is opened, dust collection through the surface of the nanofiber filter 60 is not made. The axial flow generating module 10 converts the external air introduced into the inlet 22 of the air inlet pipe 21 into an axial flow and discharges it to the outside through the air outlet pipe 23 . Here, FIG. 4 is an air flow diagram according to air circulation of the dust collecting module 100 of FIG. 2 .

As such, the dust collection module 100 according to the present embodiment reduces the dust concentration in the space while improving the air conditioning efficiency by sucking air from the outside in a state in which the diaphragm 65 is closed and purifying it and then discharging it as an axial flow when collecting dust. can do.

The dust collection module 100 according to the present embodiment can also be used to exhaust or circulate air by opening the diaphragm 65 when dust collection is not performed.

The screen 67 is installed to cover the opening 63 of the nanofiber filter 60 , and is installed outside the diaphragm 65 . The screen 67, when the air is circulated without dust collection, because the outside air directly flows into the axial flow generating module 10 through the opening 63, leaves and paper with a large size that can enter together with the outside air. It filters out objects such as entering into the opening (63). A metal mesh may be used as the screen 67 .

The nozzle 30 is installed in communication with the through hole 51 of the flange 50 to guide the external discharge of the axial flow through the outlet 24 of the air discharge pipe 23 . The nozzle 30 may be formed in a form in which the inner diameter is reduced from the inlet 31 side to the outlet 33 side so that the axial flow output from the axial flow generating module 10 can be sent farther away.

The differential pressure sensor 70 is installed on the nanofiber filter 60 to detect the differential pressure applied to the nanofiber filter 60 .

The speed of the axial flow emitted through the axial flow generating module 10 may be adjusted by varying the output of the motor 11 and the rotation speed of the fan 14 according to the differential pressure detected by the differential pressure sensor 70 . That is, in order to keep the speed of the axial flow emitted from the axial flow generating module 10 constant, the output of the motor 11 and the rotation speed of the fan 14 may be varied according to the detected differential pressure. Since the differential pressure detected in proportion to the usage time of the normal dust collecting airflow inducing fan 100 increases, the output of the motor 11 and the rotational speed of the fan 14 are increased in proportion to the usage time to keep the speed of the axial flow constant. will keep

The differential pressure detected by the differential pressure sensor 70 can be used as alarm information for the exhaustion or replacement timing of the nanofiber filter 60 . That is, by comparing the detected differential pressure with the set value, when the detected differential pressure exceeds the set value, the time of exhaustion of the nanofiber filter 60 may be notified to the user as an alarm. When the number of times the detected differential pressure exceeds the set value reaches the set number of times, information on replacement of the nanofiber filter 60 may be notified to the user as an alarm. For example, when an alarm device is installed in the dust collecting airflow inducing fan 100 , the exhaustion time and replacement time may be notified through the alarm device. Here, the alarm may output a sound or light.

If the dust collection module 100 includes a communication module, alarm information may be transmitted to the user's terminal through the communication module. Here, the user's terminal may be a dedicated terminal, a PC, a smart phone, a laptop computer, a tablet PC, a wearable device, etc. that can be utilized by a user who manages the air conditioning system.

And the compressed air supply 80 supplies compressed air to the inner space 61 of the nanofiber filter 60 to exhaust the contaminants collected on the surface of the nanofiber filter 60 . That is, the compressed air supply 80 ejects compressed air from the inside of the nanofiber filter 60 to the outside in a pulsing manner according to the exhaustion signal according to the differential pressure detected by the differential pressure sensor 70, so that the nanofiber filter 60 Contaminants collected on the surface of

The compressed air supply 80 includes a compressed air tank 81 storing compressed air, a compressed air supply pipe 83 connected to the compressed air tank 81 to supply compressed air toward the flange 50 , and compressed air. A compressed air output pipe 87 that is connected to the air supply pipe 83 and outputs compressed air to the inner space 61 of the nanofiber filter 60 through the flange 50, and a compressed air supply pipe installed in the flange 50 and an on/off valve 85 for opening and closing the connection between the 83 and the compressed air output pipe 87 . A solenoid valve may be used as the on/off valve 85 .

In addition, the dust collecting module 100 may further include a fine dust sensor. Depending on the amount of fine dust detected by the fine dust sensor, one of air circulation and dust collection can be performed.

The dust collecting module 100 according to the present embodiment as described above may be installed by connecting between the duct pipes alone or as a replacement for the filter in the air conditioning room.

[Dust collection module assembly]

Since a plurality of filters are installed in the air conditioning room, the dust collection module 100 according to this embodiment may be installed as a dust collection module assembly 200 in which a plurality are stacked in a horizontal or longitudinal direction as shown in FIG. 5 . have.

5 is a view showing the dust collecting module assembly 200 including the dust collecting module 100 according to an embodiment of the present invention.

Referring to FIG. 5 , the dust collecting module assembly 200 according to the present embodiment includes a plurality of dust collecting modules 100 stacked and arranged in an M×N matrix (at least one of M and N being a natural number equal to or greater than 2). At this time, the plurality of dust collecting modules 100 to be stacked are stacked via the flange 50 .

In this embodiment, although the structure in which the dust collecting module 100 is stacked and arranged in a 3×3 matrix is illustrated, the present embodiment is not limited thereto.

As described above, since a plurality of dust collection modules 100 according to the present embodiment are installed together in an air conditioning system rather than individually, air conditioning including dust collection through integrated management of a plurality of dust collection modules 100 using a controller can be performed.

In addition, the controller may perform air conditioning including dust collection in conjunction with air conditioning equipment, fine dust sensor, temperature sensor, humidity sensor, illuminance sensor, gas sensor, etc. included in the air conditioning system.

As described above, since the dust collection module 100 according to this embodiment has a structure in which the axial flow generating module 10 is built in the nanofiber filter 60, it is stable by minimizing the reduction in wind pressure due to the nanofiber filter 60. Air conditioning efficiency can be realized. That is, since the dust collecting module 100 according to the present embodiment generates an axial airflow, when the dust collecting module 100 according to the present embodiment is applied to an air conditioning system, an existing ventilation device can be used as it is.

Since the dust collection module 100 according to this embodiment has a structure in which the axial flow generating module 10 is built in the nanofiber filter 60, it can be manufactured in a compact size. Accordingly, it is possible to minimize the problem of insufficient installation space due to the installation of the dust collecting module 100 according to the present embodiment in the air conditioning room.

The dust collecting module 100 according to the present embodiment can reduce the dust concentration in the space while improving the air conditioning efficiency by generating an axial air flow. That is, the dust collection module 100 allows the air sucked through the axial flow generating module 10 to pass through the surface filtration type nanofiber filter 60, so that even ultrafine dust contained in the air can be efficiently collected. Since the air filtered through the nanofiber filter 60 is discharged to the outside in an axial flow by the axial flow generating module 10, it is possible to send purified air far away.

For this reason, the dust collecting module 100 according to the present embodiment can generate an airflow over a long distance to expand the shared area per unit.

The dust collection module 100 according to this embodiment varies the output of the motor 11 provided in the axial flow generating module 10 and the rotation speed of the fan 14 based on the pressure applied to the nanofiber filter 60, By maintaining a constant airflow speed, it is possible to maintain constant air conditioning efficiency and dust collection efficiency.

Since the dust collection module 100 according to this embodiment is present on the surface of the nanofiber filter 60, the dust collected contaminants exist on the surface of the nanofiber filter 60, so that the nanofiber filter 60 through compressed air input into the interior Contaminants present on the surface can be brushed off and reused.

The dust collection module 100 according to the present embodiment may provide the user with information on the time of exhaustion and replacement time based on the pressure applied to the nanofiber filter 60 .

The dust collection module 100 according to the present embodiment can comfortably maintain a place where the dust collection module 100 is installed through environmental information collected from the surrounding environment sensor and interworking operation with other air conditioning equipment.

The dust collection module 100 according to the present embodiment may be installed to replace the filter in the air conditioning room, or may be installed by connecting between duct pipes.

In addition, the dust collection module 100 according to the present embodiment can effectively perform air circulation and dust collection for the installation place by arranging an appropriate number according to the capacity of the air conditioning system and driving them to be interlocked with each other. In this case, according to the capacity or installation space of the air conditioning system, the dust collecting module 100 may be installed as the dust collecting module assembly 200 arranged in an M×N matrix (at least one of M and N being a natural number equal to or greater than 2).

On the other hand, the embodiments disclosed in the present specification and drawings are merely presented as specific examples to aid understanding, and are not intended to limit the scope of the present invention. It is apparent to those of ordinary skill in the art to which the present invention pertains that other modifications based on the technical spirit of the present invention can be implemented in addition to the embodiments disclosed herein.

10: axial flow generating module 11: motor
12: motor body 13: drive shaft
14: fan 17: fixed wing
19: fixed wing case 21: air inlet pipe
22: inlet 23: air exhaust pipe
24: outlet 25: sound absorbing material
30: nozzle 31: inlet
33: outlet 50: flange
51: through hole 60: nanofiber filter
61: inner space 62: filter body
63: opening 64: protection net
65: aperture 67: screen
70: differential pressure sensor 80: compressed air supply
81: compressed air tank 83: compressed air supply pipe
85: on-off valve 87: compressed air output pipe
100: dust collection module 200: dust collection module assembly

Claims (8)

a hollow axial flow generating module for sucking air through an inlet and discharging an axial airflow to an outlet opposite the inlet;
The axial flow generating module has an internal space in which it is built with a certain clearance, and the contaminants contained in the air sucked from the outside by the driving of the axial flow generating module are collected and removed by surface filtration, and the contaminants are removed. a tubular nanofiber filter providing air to the inlet of the axial flow generating module; and
The outlet side of the axial flow generating module is fixed, one end of the nanofiber filter corresponding to the outlet is fixed, and a flange with a through hole formed in communication with the outlet; includes,
The nanofiber filter, with respect to the flange, is longer than the length of the axial flow generating module, and the other side opposite to one side coupled to the flange is formed as an open part,
The dust collection module,
Aperture for opening and closing the inflow of air through the opening of the nanofiber filter; further comprising,
When the axial flow generating module is driven in a state in which the diaphragm is opened, air is introduced into the nanofiber filter through the diaphragm and is directly supplied to the axial flow generating module,
When the axial flow generating module is driven in a state in which the aperture is closed, the dust collecting module, characterized in that air from which contaminants are removed through the outer surface of the nanofiber filter is supplied to the axial flow generating module. delete According to claim 1, wherein the axial flow generating module,
a motor having a drive shaft protruding toward the inlet;
a fan coupled to the drive shaft and having a plurality of blades;
a fixed-wing case coupled to an outer circumferential surface of the motor and having a plurality of fixed blades disposed to face a direction opposite to a wing direction of the fan;
an air inlet pipe coupled to one side of the fixed wing case to which the fan is coupled and having the inlet through which air passing through the nanofiber filter is introduced; and
One side is coupled to the other side of the fixed-wing case and the other side is fixedly installed on the flange, and the air introduced into the air inlet pipe passes through the fan and the fixed-wing case, and is changed to an axial flow and the outlet is provided. ;
Dust collection module comprising a. delete According to claim 3, wherein the axial flow generating module,
Further comprising; sound absorbing material respectively built into the air inlet pipe or the air outlet pipe,
The dust collection module,
a nozzle installed in communication with the through hole of the flange to guide the external discharge of the axial flow through the outlet of the air discharge pipe; and
a compressed air supplier for supplying compressed air to the inner space of the nanofiber filter to dedust the contaminants collected on the surface of the nanofiber filter;
Dust collection module, characterized in that it further comprises. 4. The method of claim 3,
A differential pressure sensor installed on the nanofiber filter to detect a differential pressure applied to the nanofiber filter; further comprising,
Control the speed of the axial flow emitted through the axial flow generating module by varying the output of the motor and the rotation speed of the fan according to the differential pressure detected by the differential pressure sensor, or the exhaustion or replacement timing of the nanofiber filter Dust collection module, characterized in that providing information. A dust collecting module assembly including a plurality of dust collecting modules stacked and arranged in an M×N matrix (at least one of M and N is a natural number equal to or greater than 2),
Each of the plurality of dust collection modules,
a hollow axial flow generating module for sucking air through an inlet and discharging an axial airflow to an outlet opposite the inlet;
The axial flow generating module has an internal space in which it is built with a certain clearance, and the contaminants contained in the air sucked from the outside by the driving of the axial flow generating module are collected and removed by surface filtration, and the contaminants are removed. a tubular nanofiber filter providing air to the inlet of the axial flow generating module; and
The outlet side of the axial flow generating module is fixed, one end of the nanofiber filter corresponding to the outlet is fixed, and a flange with a through hole formed in communication with the outlet; includes,
The nanofiber filter, with respect to the flange, is longer than the length of the axial flow generating module, and the other side opposite to one side coupled to the flange is formed as an open part,
The dust collection module,
Aperture for opening and closing the inflow of air through the opening of the nanofiber filter; further comprising,
When the axial flow generating module is driven in a state in which the diaphragm is opened, air is introduced into the nanofiber filter through the diaphragm and is directly supplied to the axial flow generating module,
When the axial flow generating module is driven in a state in which the aperture is closed, the dust collecting module assembly, characterized in that air from which contaminants are removed through the outer surface of the nanofiber filter is supplied to the axial flow generating module. 8. The method of claim 7,
The plurality of dust collecting modules are dust collecting module assembly, characterized in that the stacked arrangement via the flange.

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