KR102468850B1 - Air filter system having a filter module that can change the flow direction of air - Google Patents

Abstract

In accordance with the present invention, provided is an air filter system having a filter module capable of switching air flow directions. The air filter system includes: a case (100) having a suction port (101) formed in a lower part, and a discharge port (102) formed in an upper part; a fan module (200) disposed inside the case (100), operated by applied power, and circulating air from the suction port (101) to the discharge port (102); an ionization module (300) disposed above the fan module (200), and ionizing some of the air by applying a high voltage to the air supplied by the fan module (200); a filter module (400) disposed above the ionization module (300), and filtering foreign substances out from the circulated air; and a shutter control module (500) disposed inside the case (100), and controlling a flow direction of the air passing through the filter module (400). The case (100) includes: a lower case (110) having the suction port (101) formed on a side; a middle case (120) assembled with an upper side of the lower case (110), and allowing the ionization module (300) to be disposed therein; and an upper case (130) having the discharge port (102) formed in an upward direction, and allowing the filter module (400) to be disposed therein, wherein the shutter control module (500) is disposed inside the upper case (130). Therefore, the present invention is capable of electrifying foreign substances in air and easily collecting the electrified foreign substances.

Description

Air filter system having a filter module that can change the flow direction of air}

The present invention relates to an air filter system having a filter module capable of changing the flow direction of air.

Due to changes in residential culture or the development of industry and information communication, the air in the atmosphere as well as indoors is seriously polluted due to various pollutants that are excessively discharged.

And as humans who work in these spaces unknowingly breathe polluted air, the safety of the body is seriously threatened, and various methods have been proposed to solve this problem.

For example, air pollution is suppressed through the development of various types of air purifiers, negative ion generators, and oxygen generators to purify indoor air, and regulations on the total amount of various pollutants such as automobile exhaust by country. to be.

However, there are naturally limitations in suppressing and controlling the emission of pollutants through the development of these devices or the legal system, and self-rescue measures must be taken to minimize damage from these pollutants and lead a healthy life.

In particular, in the indoor space where humans live, the indoor air is seriously polluted by various decorative materials, smoking, or harmful substances generated from various electronic devices such as computers and portable terminals. As a means, an air purifier is mainly used.

Commercially available ionizers use negative ions that receive electrons from the outside and positive ion plasma that loses electrons and has positive properties. Remove

Republic of Korea Patent Publication No. 10-2003-0075696 Republic of Korea Patent Publication No. 10-2021-0027324

The present invention has been made to solve the above conventional problems, and an object of the present invention is to provide an air filter system having a filter module capable of changing the flow direction of air.

Another object of the present invention is to provide an air filter system in which an ionization module is disposed.

The present invention is a case 100 having a suction port 101 formed at the lower portion and a discharge port 102 formed at the upper portion; a fan module 200 disposed inside the case 100, operated by applied power, and flowing air from the suction port 101 to the discharge port 102; an ionization module 300 disposed above the fan module 200 and partially ionizing the air by applying a high voltage to the air supplied by the fan module 200; a filter module 400 disposed above the ionization module 300 and filtering foreign substances from flowing air; and a shutter control module 500 disposed inside the case 100 and controlling a flow direction of air passing through the filter module 400, wherein the case 100 has a suction port 101 on a side thereof. The lower case 110 is formed; a middle case 120 assembled on an upper side of the lower case 110 and in which the ionization module 300 is disposed; An upper case 130 in which a discharge port 102 is formed in an upward direction and in which the filter module 400 is disposed, and the shutter control module 500 is disposed inside the upper case 130 An air filter system having a filter module capable of changing the flow direction of air is provided.

The fan module 200 includes a fan housing 250 disposed inside the lower case 110; a fan 220 disposed inside the fan housing 250; and a fan motor 230 coupled to the fan 220 to rotate the fan 220, and the filter module 400 includes a filter housing 450 disposed inside the upper case 130; and a filter 410 disposed inside the filter housing 450 and filtering the air supplied through the ion housing 340, and the shutter control module 500 controls the filter housing 450. a plurality of shutters 510 that cover and are rotatably assembled with the filter housing 450; a control wire 520 connecting the plurality of shutters 510; a drum 530 for winding or unwinding the control wire 520; A flow control motor 550 for rotating the drum 530 in a forward or reverse direction; may be included.

a support wire 560 connecting the plurality of shutters 510; A shutter elastic assembly 570 providing elastic force to the support wire 560 in a direction in which the filter housing 450 is closed.

The shutter 510 may be disposed above the filter 410 .

The shutter elasticity assembly 570 and the flow control motor 550 may be disposed on opposite sides of the filter housing 450 .

First, the present invention has the advantage of being able to charge foreign substances in the air by applying a high voltage to the inhaled air to ionize it, and the charged foreign substances are easily collected in the filter module.

Second, in the present invention, since the upper case is detachably assembled upward, the filter module can be easily repaired and replaced when the upper case is separated.

Third, the present invention has the advantage that the shutter control module disposed in the filter housing can control the discharge direction of the filtered air by controlling the inclination angle of the shutter.

Fourth, when the present invention is placed in a space with four sides open, the shutter is placed vertically to discharge air evenly in all directions of 360 degrees, and when placed in a space closed to at least one side, the shutter is rotated at an angle to open It has the advantage of being able to discharge the filtered air toward the space.

Fifth, the present invention has the advantage of discharging filtered air in two directions by arranging the first shutter and the second shutter inclined in different directions.

1 is a perspective view showing an air filter system according to a first embodiment of the present invention.
FIG. 2 is a front view of the air filter system in FIG. 1 with the case removed.
Figure 3 is an exploded front view of Figure 2;
Figure 4 is a front cross-sectional view showing the inside of Figure 2;
5 is a perspective view of the discharge frame shown in FIG. 3;
FIG. 6 is a partially enlarged view showing an assembly structure of the first outer counter electrode shown in FIG. 5 .
FIG. 7 is a partially enlarged view showing the assembly structure of the second outer counter electrode shown in FIG. 5 .
FIG. 8 is a partially enlarged view showing an assembly structure of the discharge electrode shown in FIG. 5 .
9 is a cross-sectional view showing a filter module according to a second embodiment of the present invention.
10 is an exemplary operation diagram of FIG. 9 .
11 is a perspective view of the filter module shown in FIG. 9;
12 is a perspective view of the filter module shown in FIG. 10;
13 is a plan view of the shutter shown in FIG. 9;
FIG. 14 is an internal cross-sectional view of the shutter elastic assembly shown in FIG. 9 .
15 is a plan view showing a shutter control module according to a third embodiment of the present invention.
FIG. 16 is a view illustrating operation of the first shutter and the second shutter shown in FIG. 15 .

Hereinafter, embodiments of the present invention will be described in detail so that those skilled in the art can easily practice the present invention with reference to the accompanying drawings. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification of the present invention, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated.

1 is a perspective view of an air filter system according to a first embodiment of the present invention, FIG. 2 is a front view of the air filter system in FIG. 1 with a case removed, FIG. 3 is an exploded front view of FIG. 2, and FIG. is a front cross-sectional view showing the inside of FIG. 2, FIG. 5 is a perspective view of the discharge frame shown in FIG. 3, and FIG. 6 is a partially enlarged view showing the assembly structure of the first outer counter electrode shown in FIG. 5, FIG. 7 is a partial enlarged view showing the assembly structure of the second outer counter electrode shown in FIG. 5 , and FIG. 8 is a partial enlarged view showing the assembly structure of the discharge electrode shown in FIG. 5 .

The air filter system according to the present embodiment includes a case 100 having a suction port 101 formed at the bottom and a discharge port 102 formed at the top, disposed inside the case 100, and operated by applied power. and a fan module 200 for flowing air from the inlet 101 to the outlet 102, and a high voltage to the air supplied by the fan module 200 and disposed above the fan module 200. It includes an ionization module 300 that partially ionizes the air by applying air, and a filter module 400 disposed above the ionization module 300 and filtering foreign substances from flowing air.

The case 100 includes a lower case 110 having a suction port 101 formed on a side thereof, and a middle case 120 assembled on the upper side of the lower case 110 and having the ionization module 300 disposed therein and an upper case 130 in which a discharge port 102 is formed in an upward direction and the filter module 400 is disposed therein.

The inlet 101 is formed to pass through the side surface of the lower case 110 .

The inlets 101 may be formed at a plurality of locations along the side of the lower case 110 .

The discharge port 102 is formed to pass through the upper surface of the upper case 130 .

An upper surface of the upper case 130 is concave downward, and a control panel 150 may be further disposed therein.

When viewed from a top view, the control panel 150 is formed in a circular shape, and the outlet 102 is disposed outside the outer edge of the control panel 150 .

Since the bottom surface of the control panel 150 is formed as a curved surface, the air discharged from the discharge port 102 can be radially diffused upward.

The fan module 200 is coupled with a fan housing 250 disposed inside the lower case 110, a fan 220 disposed inside the fan housing 250, and the fan 220, A fan motor 230 for rotating the fan 220 is included.

Inside the fan housing 250, a fan housing space 251 opened in the vertical direction is formed. The fan 220 is disposed inside the fan housing 250 .

In this embodiment, the fan 220 is a mixed flow fan.

The mixed flow fan sucks in air from the lower side and then discharges the air to the upper side. In particular, the mixed-flow fan discharges air inclined outward in the radial direction with respect to the motor shaft 231 as a reference.

The motor shaft 231 protrudes upward and is assembled with the fan 220 .

The fan 220 includes a shroud 222 having a fan inlet 221 formed on the lower side, a fan hub 224 spaced apart from the shroud 222 and disposed on the upper side, the fan hub 224 and the shroud. A plurality of blades 223 connecting the wood 222 are included.

In this embodiment, the fan hub 224 is disposed on the upper side, the shroud 224 is disposed on the lower side, and the motor shaft 231 penetrates the fan inlet 221 to the fan hub 224. Assembled.

A fan inlet 221 penetrating in the vertical direction is formed at the inner center of the shroud 224 , and the fan hub 224 is exposed through the fan inlet 221 . The fan hub 224 is disposed toward the fan inlet 221 .

Since the outer end 222b of the shroud 222 is higher than the inner end 222a, the shroud 222 is inclined upward and radially outward.

The fan hub 224 is formed in a bowl shape, is convexly disposed, and the convex portion is disposed downward.

The outer end 224b of the fan hub 224 is inclined upward and radially outward.

A fan discharge port 225 is formed between the fan hub 224 and the shroud 222 .

In this embodiment, the ionization module 300 may be selectively operated.

In this embodiment, the ionization module 300 is characterized in that only a part of the area is operated and the rest of the area is maintained in an inactive state.

The ionization module 300 is disposed inside the middle case 120, is assembled with the fan housing 250, and guides the air of the fan housing 250 to the filter module 400. An ion housing ( 340), the discharge frame 350 assembled to the ion housing 340, the discharge electrode 310 disposed inside the discharge frame 350 and to which a high voltage is applied, and the discharge frame 350 and a discharge counter electrode 320 disposed at a predetermined distance from the discharge electrode 310, and a power module (not shown) for applying a high voltage to the discharge electrode 310.

In this embodiment, the discharge counter electrode 320 is grounded.

In this embodiment, the discharge frame 350 is assembled to the top of the ion housing 340 . Since the ion housing 340 is disposed close to the filter module 400, charged foreign substances can be effectively collected in the filter module 400.

Unlike the present embodiment, the discharge frame 350 may be assembled at the inner middle or lower end of the ion housing 340 .

Inside the ion housing 340, an ion housing space 341 having upper and lower sides respectively opened is formed.

When a high voltage of 5 to 7 kv is applied to the discharge electrode 310 through the power module, the discharge electrode 310 forms a (+) polarity, and the discharge response electrode 320 forms a (-) polarity .

An ionization line for ionizing air is formed between the discharge electrode 310 and the discharge counter electrode 320 . That is, an electric field is formed between the discharge electrode 310 and the discharge counter electrode 320 by an ionization line (not shown), and fine dust passing through the electric field is charged to a (+) pole by the electric field.

When power is applied to the ionization module 300, some of the air flowing from the fan module 200 to the filter module 400 can be ionized, and foreign substances in the air can form electrodes. Foreign substances may more easily adhere to the filter module 400 .

In this embodiment, the discharge electrode 310 and the discharge counter electrode 320 are disposed on the same plane, and the ionization line may be formed in a horizontal direction.

In this embodiment, the discharge frame 350 is formed in a ring shape when viewed from a top view, and the discharge electrode 310 and the discharge counter electrode 320 are disposed inside.

When viewed from a top view, the discharge frame 350 may form a center of an imaginary circle disposed in a vertical direction, and the center of the circle may be disposed on the motor shaft 231 .

A discharge frame space 351 opened in a vertical direction is formed inside the discharge frame 350, and the discharge electrode 310 and the discharge counter electrode 320 are disposed in the discharge frame space 351.

The discharge electrodes 310 may be made of a metal material and may be formed in a wire shape, and a plurality of discharge electrodes 310 may be arranged spaced apart in a horizontal direction. A plurality of discharge electrodes 310 are arranged in parallel.

Each discharge counter electrode 320 is disposed between the discharge electrodes 310 . The discharge counter electrode 320 may be a thin metal plate and may be disposed in a vertical direction.

The discharge electrode 310 is disposed within the height of the discharge counter electrode 320 .

A plurality of discharge counter electrodes 320 may be arranged in parallel, and in this embodiment, the discharge electrode 310 and the discharge counter electrode 320 are arranged parallel to each other.

The discharge frame 350 includes an inner rim 352 to which the discharge electrode 310 and the discharge counter electrode 320 are coupled, an outer rim 354 disposed radially outside the inner rim 352, and , A connection portion 356 connecting the inner rim 352 and the outer rim 354 is included.

The inner rim 352 and the outer rim 354 form the center of the same circle, and the outer rim 354 has a larger diameter. A spaced distance 355 is formed between the inner rim 352 and the outer rim 354 in the radial direction.

The discharge electrode 310 is disposed within the height of the inner rim 352 .

In order to install the discharge electrode 310, an electrode hole 352a (see FIG. 8) penetrating the inner rim 352 is formed. The discharge electrode 310 is disposed to pass through the electrode hole 352a.

Both ends of the discharge electrode 310 are disposed to pass through the electrode hole 352a disposed to face each other. The discharge electrodes 310 may be connected to each other through a first connection electrode (not shown) disposed in the space 355 . The first connection electrode may be in close contact with the outer surface of the inner rim 352 .

To install the discharge counter electrode 354, an installation slit 357 (see FIG. 6 or 7) penetrating the inner rim 352 in a radial direction is formed. The installation slit 357 is formed in a vertical direction.

The installation slit 357 communicates the separation distance 355 and the discharge frame space 351.

The discharge counter electrode 320 includes a first outer counter electrode 321 and a second outer counter electrode 322 disposed at the spaced interval 355 and in close contact with the outer surface of the inner rim 352, A cross counter electrode 324 disposed to pass through the installation slit 357 is included.

The first outer counter electrode 321 and the second outer counter electrode 322 are disposed in opposite directions with respect to the discharge frame space 351 . The first outer counter electrode 321 and the second outer counter electrode 322 may be supported in close contact with the outer surface of the inner rim 352 .

The cross counter electrode 324 connects the first outer counter electrode 321 and the second outer counter electrode 322 and is exposed to the discharge frame space 351 .

The first outer counter electrodes 321 and the second outer counter electrodes 322 may be connected to each other and grounded through a second connection electrode (not shown) disposed in the space 355 .

Referring to FIG. 3 or 4 , the filter module 400 includes a filter housing 450 disposed inside the upper case 130 and a filter housing 450 disposed inside the filter housing 450, and the ion housing 340 ) and a filter 410 for filtering the supplied air.

The upper and lower sides of the filter housing 450 are opened, respectively, and the filter 410 is disposed therein. The filter 410 may be arranged to form a plurality of layers of various materials.

The filter housing 450 forms a ring-shaped outer surface and includes a filter support 452 protruding from the lower end toward the center.

The filter supporter 452 may support a lower edge of the filter 410 .

In this embodiment, the filter supporter 452 may be disposed to cover the inner rim 352 , the spacing 355 , and the outer rim 354 .

Therefore, the air flowing from the lower side to the upper side can be blocked by the filter supporter 452 and restricted in flow, and can be guided to the filter lower opening 454 inside the filter supporter 452 .

The fan housing 250 is disposed on the lower side, the ion housing 340 is assembled to the top of the fan housing 250, and the filter housing 450 is assembled to the top of the ion housing 340.

The fan housing 250, the ion housing 340, and the filter housing 450 are all formed in a cylindrical shape with vertical openings, and have the same inner diameter.

Unlike the present embodiment, the lower end of the fan 220 may be disposed inside the fan housing 250 and the upper end may be disposed inside the ion housing 340 . That is, the fan 220 may be disposed overlapping the fan housing 250 and the ion housing 340, and in this case, the height of the air filter system may be reduced.

A filter housing space 451 opened up and down is formed inside the filter housing 450, and the filter 410 is disposed in the filter housing space 451.

The filter 410 is disposed on the upper side of the discharge frame 350, and is specifically disposed on the upper side of the discharge electrodes 310 and the discharge counter electrodes 320.

Foreign substances charged by the ionization module 300 may be attached to the filter 410 and filtered.

In this embodiment, the filter housing 450 is disposed inside the upper case 130, and the filter housing 450 is assembled with the upper case 130. The filter 410 remains assembled inside the filter housing 450 .

Therefore, when replacement or cleaning of the filter 410 is required, the user can easily expose the filter 410 by removing the upper case 130 .

In addition, when the upper case 130 is separated from the middle case 120, the discharge frame 350 is exposed upward.

When repair or replacement of the ionization module 300 is required, the upper case 130 may be separated to expose the ionization module 300 to the outside.

When repair or replacement of the fan module 200 is required, the middle case 120 and the upper case 130 are simultaneously lifted and separated, and the fan 220 can be exposed to the outside through this.

9 is a cross-sectional view of a filter module according to a second embodiment of the present invention, FIG. 10 is an exemplary operation view of FIG. 9, FIG. 11 is a perspective view of the filter module shown in FIG. 9, and FIG. 12 is FIG. 10 is a perspective view of the filter module shown in , FIG. 13 is a plan view of the shutter shown in FIG. 9 , and FIG. 14 is an internal cross-sectional view of the shutter elastic assembly shown in FIG. 9 .

Unlike the first embodiment, the air filter system according to this embodiment is characterized in that a shutter control module 500 capable of controlling the flow direction of air passing through the filter housing 450 is further disposed.

In addition, when the air filter system does not operate or is in a stopped state, the shutter control module 500 closes the top of the filter housing 450 to prevent the filter 410 from being contaminated by external dust.

The filter housing 450 includes a filter support 452 protruding from the lower end toward the center, an upper filter opening 453 formed to penetrate the upper side, and a lower filter opening 454 formed to penetrate the lower side. do.

In this embodiment, the filter lower opening 454 is formed inside the filter supporter 452 . When viewed from a bottom view, the filter support 452 is formed in a ring shape, and the filter lower opening 454 is formed to pass through the inside of the filter support 452 .

The filter 410 may be exposed downward through the filter lower opening 454 .

In this embodiment, the shutter control module 500 controls the flow direction of air passing through the filter upper opening 453 . The shutter control module 500 may open and close the filter upper opening 453 .

The shutter control module 500 covers the filter upper opening 453 and connects a plurality of shutters 510 rotatably assembled with the filter housing 450 and the plurality of shutters 510. a control wire 520 for winding or unwinding the control wire 520, a drum 530 (see FIG. 11) for winding or unwinding the control wire 520, a flow control motor 550 for rotating the drum 530 in a forward or reverse direction, and the plurality of A support wire 560 connecting the two shutters 510 and a shutter elasticity assembly 570 providing elastic force to the support wire 560 in a direction in which the filter upper opening 453 is closed.

When the plurality of shutters 510 are arranged horizontally, the filter upper opening 453 may be closed.

Since the filter upper opening 453 is formed in a circular shape, the area and shape of each shutter 510 may be formed differently.

Referring to FIG. 13 , the shutter 510 includes a shutter body 512 that covers a part of the filter upper opening 453, and the shutter body 512 and the filter housing 450 are rotatable. It includes a shutter shaft 514 connected to each other, and a wire coupling part 516 to which the control wire 520 is coupled.

In this embodiment, the shutter shaft 514 is disposed at the lower end 512b of the shutter body 512, and the wire coupling part 516 is disposed at the upper end 512a of the shutter body 512.

An upper end 512a and a lower end 512b of the shutter body 512 are formed in parallel.

The left edge 512c and the right edge 512d of the shutter body 512 are formed in an arc shape. The left edge 512c and the right edge 512d may come into close contact with the edge of the circle forming the filter upper opening surface 453 .

The left edge 512c and the right edge 512d are left-right symmetrical.

The shutter shaft 514 includes a first shutter shaft 514a protruding leftward from the left edge 512c and a second shutter shaft 514b protruding rightward from the right edge 512d.

The first shutter shaft 514a and the second shutter shaft 514b are arranged in a line.

The wire coupling part 516 protrudes upward from the upper end 512a. In this embodiment, the wire coupling part 516 is disposed in the middle of the left edge 512c and the right edge 512d.

The control wire 520 may be fixed to the wire coupling part 516 . When the control wire 520 is pulled, the shutter body 512 is rotated about the first shutter shaft 514a and the second shutter shaft 514b.

The wire coupling part 516 may be supported on an upper surface of an adjacent shutter 510 .

That is, the wire coupling portion 516 may maintain an overlapping state with the adjacent shutter 510 .

Since the first shutter shaft 514a and the second shutter shaft 514b are disposed at the bottom, when the shutter 510 rotates, the entire shutter body 512 is inclined upward toward the filter housing 450 or It can be upright, through which the flow direction of air can be effectively controlled.

When the shutter body 512 is disposed inclined, air can be discharged in an inclined direction, and when the shutter body 512 is upright, air can flow upward, and the shutter body 512 can be horizontally When disposed, the filter upper opening surface 453 may be closed.

The control wires 520 are respectively coupled to wire coupling parts 516 disposed on the plurality of shutters 510 . In this embodiment, one control wire 520 simultaneously controls a plurality of shutters 510 . So, when the control wire 520 is wound or unwound, a plurality of shutters 510 can be simultaneously operated.

The control wire 520 is fixed to the drum 530 and can be wound or unwound.

The flow control motor 550 rotates the drum 530 in a forward or reverse direction to wind or unwind the control wire 520 .

In this embodiment, the flow control motor 550 is disposed on the outer surface of the filter housing 450, and the drum 530 is also disposed on the outer surface of the filter housing 450.

A drum bracket 540 protrudes radially outward from an outer surface of the filter housing 450, and the drum 530 is rotatably assembled to the drum bracket 540.

The flow control motor 550 may be fixed to the drum bracket 540 or the filter housing 450 .

Since the control wire 520 connects the shutter 510 and the drum 530, it must be disposed on the upper and outer surfaces of the filter housing 450 and turned 90 degrees.

In order to minimize friction between the control wire 520 and the filter housing 450, a first wire roller 581 is disposed on the upper side of the filter housing 450, and a first wire roller 581 is disposed on the outer circumferential surface of the filter housing 450. Two wire rollers 582 are disposed.

The second wire roller 582 is disposed above the drum 530 .

The first wire roller 581 and the second wire roller 582 are rotatably disposed, respectively, and the control wire 520 is supported by the first wire roller 581 and the second wire roller 582 .

When the control wire 520 is wound or unwound, the first wire roller 581 and the second wire roller 582 rotate to reduce friction, thereby minimizing friction and operating noise.

The shutter elastic assembly 570 includes an elastic box 575 disposed on an outer surface of the filter housing 450 and an elastic member coupled to the support wire 560 and accommodated in the elastic box 575 ( 572), and an elastic roller 584 disposed on an outer circumferential surface of the filter housing 450 and supporting the support wire 560.

The shutter elastic assembly 570 is disposed on the opposite side of the flow control motor 550 based on the filter housing 450 . In particular, the flow control motor 550 and the elastic box 575 are disposed in opposite directions.

In this embodiment, a main spring is used as the elastic member 572 and provides an elastic force in a direction in which the shutter 510 is closed. That is, the elastic member 572 provides an elastic force in the direction in which the control wire 520 is released.

The flow control motor 550 may pull the control wire 520 to open the shutter 510 with a force greater than the elastic force of the elastic member 572 .

Even when the shutter 510 closes the filter upper opening 453, the control wire 520 is pulled with a force slightly smaller than the elastic force of the elastic member 572 to control the closing speed of the shutter 510. can

Specifically, the flow control motor 550 pulls the control wire 520 with a force of 90% of the elastic force of the elastic member 572 and controls the shutter 510 to close slowly.

Since the shutter 510 remains pulled in both directions by the tension of the control wire 520 and the tension of the support wire 560, shaking or vibration of the shutter 510 can be minimized.

When the flow rate of air passing through the filter housing 450 is high, the shutter 510 may vibrate due to the air flow, but the tension of the control wire 520 and the tension of the support wire 560 Since it is supported by the air flow, it is possible to suppress vibration due to the air flow.

In addition, even if the shutter 510 is inclined, the inclination angle can be effectively maintained because it is supported on both sides by the tension of the control wire 520 and the tension of the support wire 560 .

In this embodiment, the support wire 560 connects the end of the elastic member 572 and the wire coupling part 561' of the shutter 510 closest to the elastic roller 584. Unlike the present embodiment, the support wire 560 may be coupled to at least one wire coupling part 561 of the plurality of shutters 510 .

The elastic roller 584 may support the support wire 560 and reduce friction with the support wire 560 .

The elastic member 572 may be disposed by being wound around the elastic box 575, and may be drawn out of the elastic box 575 when the support wire 560 is pulled.

A support boss 573 for supporting the support wire 560 or the elastic member 572 is disposed inside the elastic box 575, and the elastic member 572 or the support wire passes through the support boss 573. 560 can be easily maintained in a redirected state.

Since the remaining configurations are similar to those of the first embodiment, detailed descriptions thereof are omitted.

FIG. 15 is a plan view illustrating a shutter control module according to a third embodiment of the present invention, and FIG. 16 is an exemplary view illustrating the operation of the first shutter and the second shutter shown in FIG. 15 .

The shutter control module 1500 according to this embodiment is characterized in that it can control the air passing through the filter housing 450 in different directions.

The shutter control module 1500 includes a plurality of first shutters 1510 covering the filter upper opening 453 and rotatably assembled with the filter housing 450, and the filter housing 450. and a plurality of second shutters 1520 rotatably assembled, a first control wire 521 connecting the plurality of first shutters 1510, and connecting the plurality of second shutters 1520. A second control wire 522, a first drum 531 for winding or unwinding the first control wire 521, a second drum 532 for winding or unwinding the second control wire 522, A first flow control motor 551 for rotating the first drum 531 in a forward or reverse direction, a second flow control motor 552 for rotating the second drum 532 in a forward or reverse direction, and The first support wire 561 connecting the first shutters 1510, the second support wire 562 connecting the plurality of second shutters 1520, and the filter upper opening 453 are closed. A first shutter elasticity assembly 571 providing elastic force to the first support wire 561 in the direction, and a first shutter elastic assembly 571 providing elastic force to the second support wire 562 in the direction in which the filter upper opening 453 is closed. 2 shutter elastic assembly 572.

The configuration of the first shutter elasticity assembly 571 and the second shutter elasticity assembly 572 is the same as that of the shutter elasticity assembly 570 of the second embodiment.

The configuration of the first support wire 561 and the second support wire 562 is also the same as the configuration of the support wire of the second embodiment.

The configuration of the first control wire 521 and the second control wire 522 is also the same as the configuration of the control wire of the second embodiment.

The configuration of the first flow path control motor 551 and the second flow path control motor 552 is also the same as that of the flow path control motor of the second embodiment.

In this embodiment, the first shutter 1510 and the second shutter 1520 may rotate relative to each other and are rotatably assembled through a connector rotation shaft 1530. In particular, the first shutter 1510 and the second shutter 1520 may be rotated in opposite directions, and may be stationary and maintained in an crossed state.

When the first shutter 1510 and the second shutter 1520 are arranged in a line, they may have the shape of the shutter 510 of the second embodiment.

A plurality of first shutter bodies 1510 may form a semicircle covering the filter upper opening surface 453, and a plurality of second shutter bodies 1520 cover the filter upper opening surface 453. The remaining semicircles can be formed.

The first shutter 1510 includes a first shutter body 1512 capable of covering a part of the filter upper opening 453, and a rotatable first shutter body 1512 and filter housing 450. It includes a first shutter shaft 1514 that is connected to the first shutter shaft 1514 and a first wire coupling part 1516 to which the first control wire 521 is coupled.

In this embodiment, the first shutter shaft 1514 is disposed at the lower end 1512b of the first shutter body 1512, and the first wire coupling part 1516 is at the upper end of the first shutter body 1512. (1512a).

In this embodiment, the upper end 1512a and the lower end 1512b of the first shutter body 1512 are formed in parallel.

The radially outer edge 1512c of the first shutter body 1512 is formed in an arc shape, and the inner edge 1512d is formed in a straight line. The outer edge 1512c may come into close contact with the inner circumferential surface of the filter housing 450 .

The outer edges 1512c of the plurality of first shutter bodies 1512 are formed toward the center of curvature of the filter upper opening 453.

The second shutter 1520 includes a second shutter body 1522 capable of covering a part of the filter upper opening 453, and the second shutter body 1522 and the filter housing 450 are rotatable. It includes a second shutter shaft 1524 and a second wire coupling part 1526 to which the second control wire 522 is coupled.

In this embodiment, the second shutter shaft 1524 is disposed at the lower end 1522b of the second shutter body 1522, and the second wire coupling part 1526 is at the upper end of the second shutter body 1522. 1522a.

In this embodiment, the upper end 1522a and the lower end 1522b of the second shutter body 1522 are formed in parallel.

The radially outer edge 1522c of the second shutter body 1522 is formed in an arc shape, and the inner edge 1522d is formed in a straight line. The outer edge 1522c may come into close contact with the inner circumferential surface of the filter housing 450 .

The outer edges 1522c of the plurality of second shutter bodies 1520 are formed toward the center of curvature of the filter upper opening 453.

The inner edge 1512d of the first shutter body 1512 and the inner edge 1522d of the second shutter body 1522 are formed in parallel straight lines. The connector rotation shaft 1530 is rotatably assembled to the inner edge 1512d of the first shutter body 1512 and the inner edge 1522d of the second shutter body 1522.

When the inner edge 1512d of the first shutter body 1512 and the inner edge 1522d of the second shutter body 1522 are arranged in a line, they can operate like the shutter 510 of the second embodiment. .

The first flow control motor 551 rotates the first shutter 1510 and the second flow control motor 552 rotates the second shutter 1520 .

The first shutter 1510 and the second shutter 1520 can be rotated in different directions through the first flow control motor 551 and the second flow control motor 552, and through this, the filter upper opening ( 453) can be controlled in different directions.

In addition, the inclination angle of the discharged air may be adjusted by setting the inclination angle of the first shutter 1510 and the inclination angle of the second shutter 1520 differently.

When the first shutter 1510 and the second shutter 1520 are arranged orthogonally, the air passing through the filter upper opening 453 can easily form an upward air flow, through which the air is discharged. The filtered air can be raised higher.

For example, when disposed in an open space on four sides, the first shutter 1510 and the second shutter 1520 may be disposed orthogonally or vertically to uniformly discharge air in all directions of 360 degrees.

In addition, when disposed in a space closed on at least one side, there is an advantage in that filtered air can be discharged toward the open space by rotating the first shutter 1510 and the second shutter 1520 obliquely toward the open space. When the first shutter 1510 and the second shutter 1520 are inclined in opposite directions, filtered air can be provided in two directions.

In addition, through the first flow path control motor 551 and the second flow path control motor 552, the filtered air passing through the filter upper opening 453 can be controlled in the same direction as in the second embodiment.

As described above, the shutter control module 1500 according to the present embodiment has an advantage of being able to more effectively respond to an open space by controlling the first shutter 1510 and the second shutter 1520.

Since the remaining configurations are similar to those of the second embodiment, detailed descriptions thereof are omitted.

In the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments and should not be defined, but should be defined by not only the scope of the claims to be described later, but also those equivalent to the scope of these claims.

100: case 110: lower case
120: middle case 130: upper case
200: fan module 220: fan
230: motor 250: fan housing
300: ionization module 310: discharge electrode
320: discharge counter electrode 340: ion housing
350: discharge frame 400: filter module
410: filter 450: filter housing
500: shutter control module 510: shutter
520: control wire 530: drum
540: drum bracket 550: flow control motor
560: support wire 570: shutter elastic assembly

Claims (5)

a case 100 having a suction port 101 formed at the lower portion and a discharge port 102 formed at the upper portion;
a fan module 200 disposed inside the case 100, operated by applied power, and flowing air from the suction port 101 to the discharge port 102;
an ionization module 300 disposed above the fan module 200 and partially ionizing the air by applying a high voltage to the air supplied by the fan module 200;
a filter module 400 disposed above the ionization module 300 and filtering foreign substances from flowing air; and
A shutter control module 500 disposed inside the case 100 and controlling a flow direction of air passing through the filter module 400,
The case 100,
Lower case 110 having a suction port 101 formed on the side;
a middle case 120 assembled on an upper side of the lower case 110 and in which the ionization module 300 is disposed; and
An upper case 130 having a discharge port 102 formed in an upward direction and in which the filter module 400 is disposed,
The fan module 200,
a fan housing 250 disposed inside the lower case 110; a fan 220 disposed inside the fan housing 250; A fan motor 230 coupled to the fan 220 to rotate the fan 220; includes,
The filter module 400,
a filter housing 450 disposed inside the upper case 130;
A filter 410 disposed inside the filter housing 450 and filtering the air supplied through the ionization module 300;
The shutter control module 500,
a plurality of shutters 510 that cover the filter housing 450 and are rotatably assembled with the filter housing 450;
a control wire 520 connecting the plurality of shutters 510;
a drum 530 for winding or unwinding the control wire 520;
a flow control motor 550 for rotating the drum 530 in a forward or reverse direction;
a support wire 560 connecting the plurality of shutters 510; and
An air filter system having a filter module capable of changing a flow direction of air, including a shutter elastic assembly 570 providing elastic force to the support wire 560 in a direction in which the filter housing 450 is closed. delete delete The method of claim 1,
An air filter system having a filter module in which the shutter 510 is disposed above the filter 410 and is capable of changing a flow direction of air. The method of claim 1,
The air filter system having a filter module capable of changing a flow direction of air in which the shutter elastic assembly (570) and the flow control motor (550) are disposed on opposite sides of the filter housing (450).

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