KR102300504B1 - Air purifier comprising a bidirectional discharge flow path - Google Patents

Abstract

An air purifier comprising an air cleaning module (10), the air cleaning module (10) comprising:
A blowing fan 100 configured to suck outside air; A flow path dividing unit 200 to which the blowing fan 100 is rotatably mounted; A first flow path unit 310 located at one side of the flow path dividing unit 200 ) and a flow path part 300 including a second flow path part 320 located on the other side opposite to the blowing fan 100 with respect to the one side of the flow path division part 200 ; and a housing 400 accommodating the blowing fan 100, the flow path dividing part 200 and the flow path receiving part 300 therein, the housing 400 is located on one side thereof, The first opening 410 and the other side of the first opening 410 for fluidly connecting the first flow path 310 and the outside of the housing 400 are located, and the second flow path 320 and the housing 400 . ) and a second opening 420 that fluidly connects the outside, and the outside air sucked by the blower fan 100 passes through the first flow path part 310 and the second flow path part 320 . It provides an air purifier, characterized in that discharged to the outside through any one or more.

Description

Air purifier comprising a bidirectional discharge flow path

The present invention relates to an air cleaner and a method for controlling the same, and more particularly, to an air cleaner including an air cleaning module using a bidirectional discharge flow path.

With the increase of fine dust, interest in indoor air quality is increasing. In the prior art, ventilation was performed by opening a window and introducing outside air to improve the indoor air quality. However, as the concentration of fine dust contained in the outside air increases, it is difficult to expect a great effect in purifying the indoor air through ventilation.

Accordingly, an air purifier is in the spotlight as a method for improving indoor air quality without ventilation through a window. The air purifier includes a HEPA filter, a dust filter, and the like, and performs a function of purifying the indoor air by filtering the indoor air sucked into the device and then discharging it again.

In addition, a technique for a method of performing air cleaning for spaces of various areas by diversifying the air purification capabilities of the air purifier has been disclosed. This is due to the fact that since the width of the indoor space in which the air purifier is located is not always the same, the efficiency of indoor air cleaning cannot be maximized with the conventional air purifier having a fixed air purifying ability.

Korean Patent Laid-Open Publication No. 10-2018-0065164 discloses a complex type air purifier that can be used by combining an electrostatic main body air purifier and a low-temperature plasma type air purifier for movement.

However, in this type of air purifier, since the cleaning methods of the main body air purifier and the portable air purifier are different, when combined, it is possible to maximize the effect of air cleaning, but the functions performed by each module are different. There is a limit in that the efficiency of air cleaning can be improved only when all the modules are moved to perform air cleaning.

Korean Patent Document No. 10-1830095 discloses a small air purifier having a compact shape to be movable.

By the way, when this type of air purifier is used in a small space, it can be expected to improve the efficiency of air cleaning, but when used in a large space, there is a limit in capacity to perform air cleaning with one air purifier, so an additional air purifier It still includes the limitation of having to provide more.

(Patent Document 1) Korean Patent Publication No. 10-2018-0065164 (2018.06.18.)

(Patent Document 2) Korean Patent Document No. 10-1830095 (2018.02.12.)

An object of the present invention is to provide an air purifier capable of diversifying the air purifying capacity according to the conditions of the indoor space by combining or stacking air purifying modules capable of independently performing an air purifying function according to the area of various indoor spaces. there is

In order to achieve the above object, the present invention provides an air cleaner including an air cleaning module (10), wherein the air cleaning module (10) includes: a blowing fan (100) configured to suck in outside air; The flow path dividing unit 200 to which 100 is rotatably mounted; a flow path part 300 including a second flow path part 320 positioned on the other side opposite to the blowing fan 100; and a housing 400 accommodating the blowing fan 100, the flow path dividing part 200 and the flow path receiving part 300 therein, the housing 400 is located on one side thereof, The first opening 410 and the other side of the first opening 410 for fluidly connecting the first flow path 310 and the outside of the housing 400 are located, and the second flow path 320 and the housing 400 . ) and a second opening 420 that fluidly connects the outside, and the outside air sucked by the blower fan 100 passes through the first flow path part 310 and the second flow path part 320 . It provides an air purifier, characterized in that discharged to the outside through any one or more.

In addition, the first flow path opening and closing portion 312 provided at one side of the first opening 410 configured to open and close the first opening 410; and a second flow passage opening/closing part 322 provided at one side of the second opening 420 and configured to open and close the second opening 420 ; It further includes, and the first opening 410 and the second opening 420 may be disposed to face each other in the housing 400 .

In addition, the first flow passage opening and closing part 312 and the second flow passage opening and closing part 322 may operate independently.

In addition, the flow path dividing unit 200 may include: a first flow path unit coupling groove 210 formed on the one side of the flow path dividing unit 200 ; and a second flow passage coupling groove 220 formed on the other side opposite to the blowing fan 100 with respect to the one side of the flow passage dividing part 200; 310 may be detachably coupled to the first flow passage coupling groove 210 , and the second flow passage 320 may be detachably coupled to the second flow passage coupling groove 220 .

In addition, the discharge port of the first flow path part 310 is installed in the first opening 410 , the discharge port of the second flow path part 320 is installed in the second opening 420 , and the first flow path The inlet of the part 310 and the inlet of the second flow path 320 are installed to communicate with the blowing fan 100, respectively, so that the outside air sucked by the blowing fan 100 passes through the first opening 410 ) and the second opening 420 may be characterized in that it is discharged to the outside.

According to the present invention, each air cleaning module can independently perform an air cleaning function, and can constitute an air cleaner by being stacked and combined in the vertical direction. It can be implemented in various capacities.

In addition, each air cleaning module includes a flow path through which air is discharged in both directions, and by adjusting the air discharge direction and discharge amount as necessary, an air cleaning mode suitable for indoor air conditions can be performed.

Furthermore, various modes for air cleaning can be performed just by inputting a desired mode without the user manually operating the air, so that air cleaning can be conveniently performed.

1 is a perspective view illustrating an air cleaning module according to an embodiment of the present invention.
Fig. 2 is a front view showing the front of the air cleaning module of Fig. 1;
FIG. 3 is a perspective view illustrating a coupling relationship between a blower fan and a flow path dividing unit of the air cleaning module of FIG. 1 .
4 is a front view and a rear view showing the blowing fan and the flow passage division of FIG. 3 .
FIG. 5 is a view illustrating a state in which a flow passage unit is coupled to the flow passage dividing unit of FIG. 3 .
FIG. 6 is a view illustrating a first flow path opening/closing unit, a second flow path opening/closing unit, and a housing of the air cleaning module of FIG. 1 .
FIG. 7 is a view showing the operation of the air cleaning module of FIG. 1 .
FIG. 8 is a block diagram showing the configuration of a control unit of the air cleaning module of FIG. 1 .
9 is a view showing an air purifier in which a plurality of air purifying modules of FIG. 1 are provided and stacked.
10 is a diagram illustrating an operation of the air purifier in a normal mode according to an embodiment of the present invention.
11 is a front view (a) and a plan view (b) illustrating the operation of the rapid cleaning mode of the air purifier according to an embodiment of the present invention.
12 is a front view (a) and a plan view (b) illustrating the operation of the remote cleaning mode of the air purifier according to an embodiment of the present invention.
13 is a view showing the operation of the short-distance cleaning mode and the short-distance intensive cleaning mode of the air purifier according to an embodiment of the present invention.
14 is a flowchart illustrating a process in which the air purifier is controlled according to motion information detected by a motion sensor according to an embodiment of the present invention.
15 is a flowchart illustrating a process in which the air purifier is controlled according to dust information detected by a dust sensor according to an embodiment of the present invention.

Hereinafter, an air cleaning module, an air cleaner, and a method for controlling the air cleaner according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The terms “front side”, “rear side”, “left”, “right”, “top”, and “bottom” used in the following description will be understood with reference to the coordinate system shown in FIG. 1 .

The term "capacity" used in the following description encompasses all concepts that can quantitatively express the amount that the air purifier or air cleaning module can perform, such as the volume, volume, and area of the room.

The term “outside air” used in the following description refers to polluted air that is located outside the air cleaning module 10 and has not undergone an air cleaning process.

The term “clean air” used in the following description refers to air that has undergone an air cleaning process by the air cleaning module 10 .

The term "normally sized dust" used in the following description refers to dust having a relatively larger particle size than that of "fine dust".

1. Description of the air cleaning module (10)

The air cleaning module 10 may include components performing each function for performing air cleaning therein, and may independently perform air cleaning.

In addition, the air cleaning module 10 according to the embodiment of the present invention is provided as a single module part, so that the air cleaning function can be performed by itself, and when a large air cleaning capacity is required according to use, it can be stacked or By being combined, it is possible to form the air purifier 1 having a different capacity, which will be described in detail later.

1 and 2 , the air cleaning module 10 according to the illustrated embodiment includes a blowing fan 100 , a flow path dividing unit 200 , a flow path unit 300 , a housing 400 , and a sensor unit 500 . ) is included. In addition, as will be described later, the air cleaning module 10 according to an embodiment of the present invention further includes a control unit 600 (see FIG. 10 ).

(1) Description of the blowing fan 100

1 to 5 , the air cleaning module 10 according to the illustrated embodiment includes a blowing fan 100 .

The blowing fan 100 sucks in the outside air of the air cleaning module 10, and after a cleaning process for the outside air sucked by the filter unit (not shown) is performed, clean air is again supplied to the air cleaning module 10 It provides power for discharging to the outside of

The blowing fan 100 is accommodated inside the housing 400 to be described later.

In order to perform the purification process of the outside air sucked in by the blowing fan 100 , a separate filter unit (not shown) may be located at an appropriate location, such as inside or outside the blowing fan 100 .

In the illustrated embodiment, the blowing fan 100 is provided as a cylindrical shape in which a plurality of blades are formed on its outer circumferential surface, but the shape may be provided as any other structure capable of sucking in outside air and re-emitting the sucked air.

As will be described later, an air communication port (not shown) for providing a flow path through which air can communicate may be formed in the housing 400 to be described later for suction of outside air by the blowing fan 100 .

A motor 110 is provided in the center of the blowing fan 100 to provide power for the blowing fan 100 to rotate. The position and capacity of the motor 110 are preferably determined according to the shape and size of the blowing fan 100 .

The blowing fan 100 is rotatably coupled to the flow path dividing unit 200 to be described later by a separate fastening member (not shown).

Referring to FIG. 8 , in one embodiment, the blowing fan 100 may suck in outside air from the front side and the rear side (A), and discharge clean air to the left and right sides (B).

As will be described later, each air cleaning module 10 may be provided in plurality to function as the air cleaner 1 . At this time, whether the power of the blowing fan 100 of each air cleaning module 10 is applied and the rotation speed Any one or more of them can be independently controlled.

(2) Description of the flow path dividing part 200

1 to 5 , the air cleaning module 10 according to the illustrated embodiment includes a flow path dividing unit 200 .

A blowing fan 100 is rotatably coupled to the flow path dividing unit 200 , and a flow path unit 300 to be described later is coupled to the flow path to be described later after the outside air introduced by the blowing fan 100 undergoes a cleaning process. to be discharged through the unit 300 (see FIG. 3 ).

In the illustrated embodiment, the flow path dividing unit 200 is formed by combining the upper plate material, the lower plate material, and the blowing fan 100 coupling plate positioned therebetween, but the shape and size are changeable.

The flow path dividing part 200 is accommodated inside the housing 400 to be described later.

The flow path dividing part 200 includes a first flow path part coupling groove 210 and a second flow path part coupling groove 220 .

1) Description of the first flow path coupling groove 210

Referring further to FIG. 4 , the first flow path coupling groove 210 is a groove formed in the flow path dividing part 200 , and the first flow path part 310 of the flow path part 300 to be described later is a first flow path coupling groove. coupled to 210 . In the illustrated embodiment, the first flow path coupling groove 210 is formed on one surface of the front side of the flow path dividing unit 200, and its position is changeable.

In an embodiment, the first flow path part 310 to be described later may be inserted and coupled to the first flow path part coupling groove 210 . In addition to this, various coupling methods may be used, but in consideration of maintenance and the like, it is preferable that the first flow path part 310 to be described later is detachably coupled to the first flow path part coupling groove 210 .

The position and shape of the first flow path coupling groove 210 is preferably formed to correspond to the position and shape of the first flow path part 310 to be described later.

In addition, the shape of the first flow path coupling groove 210 is preferably formed to be complementary to the second flow path coupling groove 220 to be described later, which is the air cleaning module 10 according to the embodiment of the present invention. This is to discharge clean air in both directions.

In addition, when a first flow path part 310 to be described later is coupled to the first flow path part coupling groove 210 , the clean air discharged from the blowing fan 100 is a first flow path part 310 and a second flow path part to be described later. It may be discharged to the outside of the air cleaning module 10 through any one or more of 320, a detailed description thereof will be described later.

2) Description of the second flow passage coupling groove 220

Referring further to FIG. 4 , the second flow path part coupling groove 220 is a groove formed in the flow path dividing part 200 , and the second flow path part 320 of the flow path part 300 to be described later is a second flow path part coupling groove. is coupled to 220 . In the illustrated embodiment, the second flow path coupling groove 220 is formed on one surface of the rear side of the flow path dividing unit 200, and the position thereof is changeable.

However, it is preferable that the position of the second flow path part coupling groove 220 is complementary to the position of the first flow path part coupling groove 210 .

In an embodiment, the second flow path part 320 to be described later may be inserted and coupled to the second flow path part coupling groove 220 . In addition to this, various coupling methods may be used, but in consideration of maintenance and the like, it is preferable that the second flow path part 320 to be described later is detachably coupled to the second flow path part coupling groove 220 .

It is preferable that the position and shape of the second flow path part coupling groove 220 correspond to the position and shape of the second flow path part 320 to be described later.

In addition, the shape of the second flow passage coupling groove 220 is preferably formed to be complementary to the above-described first flow passage coupling groove 210 , which is the air cleaning module 10 according to the embodiment of the present invention. This is to discharge clean air in both directions.

Specifically, as in the illustrated embodiment, when the above-described first flow path part coupling groove 210 is formed to face to the left, the second flow path part coupling groove 220 is formed to face the right side, and conversely, the above-described first flow path part coupling groove 220 is formed to face right. When the first flow path coupling groove 210 is formed to face the right, the second flow path coupling groove 220 is preferably formed to face the left side.

In addition, when a second flow path part 320 to be described later is coupled to the second flow path part coupling groove 220 , the clean air discharged from the blower fan 100 is a first flow path part 310 and a second flow path part to be described later. It may be discharged to the outside of the air cleaning module 10 through any one or more of 320, a detailed description thereof will be described later.

(3) Description of the flow path part 300

1, 2 and 5 , the air cleaning module 10 according to the illustrated embodiment includes a flow path unit 300 .

The flow path unit 300 includes a first flow path unit 310 and a second flow path unit 320 to be described later, and after the outside air sucked by the blower fan 100 undergoes an air cleaning process, air as clean air A flow path for discharging to the outside of the clean module 10 is formed.

In addition, the air cleaning module 10 according to an embodiment of the present invention may select one or more directions in which the clean air is discharged. A second flow path opening/closing part 322 is provided.

The word "moving" used in the following description means that the location is changed from a specific location to another location.

1) Description of the first flow path part 310

The first flow path part 310 forms a flow path for the clean air that is sucked in by the blowing fan 100 and has undergone a cleaning process to be discharged from the air cleaning module 10 according to an embodiment of the present invention to the outside.

In the illustrated embodiment, the first flow path part 310 is provided in the form of a case, and is inserted into the first flow path part coupling groove 210 of the flow path division part 200 , and is positioned on the front side of the blowing fan 100 . do.

Looking at the shape of the first flow path part 310 , the portion surrounding the blowing fan 100 is formed in a circular shape to correspond to the shape of the blowing fan 100 , and the left side is adjacent to the left side of the housing 400 to be described later. It is extended so as to be provided in the form of a cochlear tube communicatively connected to the first opening 410 of the housing 400 to be described later, but it is natural that the shape of the first flow path part 310 can be changed.

A first flow passage opening/closing part 312 is movably provided at a portion where the first flow passage part 310 is positioned adjacent to the left side of the housing 400 to be described later.

The first flow path opening/closing part 312 allows or prevents clean air from being discharged through the first flow path part 310 by opening or closing the first opening 410 of the housing 400 to be described later.

The first flow path opening/closing part 312 may be opened and closed by rotating the first opening 410 of the housing 400 to be described later. For example, it may be provided in a form capable of slide movement or folder type movement.

The first flow path opening and closing part 312 may move between a first open position for completely opening the first opening 410 of the housing 400 to be described later and a first closed position for completely closing the first opening 410 to be described later. have.

In other words, the first flow path opening/closing part 312 may be positioned to completely open, completely close, or only partially open the first opening 410 , which will be described later. Accordingly, the flow rate of the clean air discharged from the first flow path part 310 may be adjusted.

The movement of the first flow passage opening and closing part 312 may be performed independently of the movement of the second flow passage opening and closing part 322 to be described later. In addition, as will be described later, when the air cleaning module 10 according to an embodiment of the present invention is operated to perform various modes, in a specific mode, the movement of the first flow path opening/closing unit 312 moves to a second flow path opening/closing unit ( 322) can proceed accordingly.

The relationship between the movement of the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 to be described later and the movement of the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 to be described later in each mode are described in detail. to be described later.

2) Description of the second flow path part 320

The second flow path part 320 forms a flow path for the clean air that has been sucked in by the blowing fan 100 and has undergone a cleaning process to be discharged from the air cleaning module 10 according to an embodiment of the present invention to the outside.

In the illustrated embodiment, the second flow path part 320 is provided in the form of a case, and is inserted into the second flow path part coupling groove 220 of the flow path dividing part 200 , and is located on the rear side of the blowing fan 100 . do.

Looking at the shape of the second flow path part 320 , the portion surrounding the blowing fan 100 is formed in a circular shape to correspond to the shape of the blowing fan 100 , and the left side is adjacent to the right side of the housing 400 to be described later. It is extended so as to be provided in the form of a cochlear tube that is fluidly connected to the second opening 420 of the housing 400 to be described later, but it is natural that the shape of the second flow path part 320 can be changed.

A second flow passage opening/closing part 322 is movably provided at a portion where the second flow passage part 320 is positioned adjacent to the right side of the housing 400 to be described later.

The second flow path opening/closing part 322 allows or prevents clean air from being discharged through the second flow path part 320 by opening or closing the second opening 420 of the housing 400 to be described later.

The second flow path opening/closing part 322 may be opened and closed by rotating the second opening 420 of the housing 400 to be described later, but other methods for opening and closing the second opening 420, such as For example, it may be provided in a form capable of slide movement or folder type movement.

The second flow path opening/closing part 322 can move between a second open position that completely opens the second opening 420 of the housing 400 to be described later and a second closed position that completely closes the second opening 420 that will be described later. have.

In other words, the second flow path opening/closing part 322 may be positioned to completely open, completely close, or only partially open the second opening 420 , which will be described later. Accordingly, the flow rate of the clean air discharged from the second flow path part 320 may be adjusted.

The movement of the second passage opening and closing part 322 may be performed independently of the movement of the first passage opening and closing part 312 . In addition, as will be described later, when the air cleaning module 10 according to an embodiment of the present invention is operated to perform various modes, in a specific mode, the movement of the second flow passage opening/closing unit 322 is caused by the first flow passage opening/closing unit 312 . can proceed according to the movement of

The relationship between the movement of the first passage opening and closing unit 312 and the second passage opening and closing unit 322 and the movement of the first passage opening and closing unit 312 and the second passage opening and closing unit 322 in each mode will be described later. .

(4) Description of the housing 400

1, 2, 6 and 7 , the air cleaning module 10 according to the illustrated embodiment includes a housing 400 .

The housing 400 forms the outside of the air cleaning module 10 , and accommodates the above-described blowing fan 100 , the flow path dividing unit 200 , and the flow path unit 300 inside the housing 400 . In addition, the control unit 600 to be described later may also be accommodated inside the housing 400 .

In addition, in the illustrated embodiment, the sensor unit 500 to be described later is provided on the upper side of the front side of the housing 400 .

The housing 400 may be formed of a transparent material. When the air cleaning module 10 is used, the time when cleaning, maintenance, etc. of the blower fan 100, the filter unit (not shown), the flow path division unit 200 and the flow path unit 300, etc. are required according to the passage of time to make it easier to understand.

As will be described later, the air cleaning module 10 according to the embodiment of the present invention may be stacked in a vertical direction and coupled to each other. For this purpose, a coupling member (not shown) may be provided on the lower side of the housing 400 . .

Alternatively, in consideration of the case where one air cleaning module 10 is used independently, a mounting member (not shown) may be provided on the lower side of the housing 400 .

In the illustrated embodiment, the housing 400 is provided in the shape of a cube or a rectangular parallelepiped, but the shape may be changed.

However, considering that one feature of the air cleaning module 10 according to the embodiment of the present invention is that it is provided in a modular form and can be combined according to the required capacity, no matter what shape it is provided in, it is a shape suitable for combining with each other. It is preferable to be provided with

It is preferable that at least one side surface of the housing 400 is provided with an opening (not shown) for forming a flow path through which the air can communicate so that outside air can be sucked by the blowing fan 100 .

In one embodiment, the blowing fan 100 sucks outside air from the front side and the rear side, and it is preferable that one or more openings (not shown) are provided on the front side and the rear side of the housing 400 .

The housing 400 includes a first opening 410 , a second opening 420 , a front housing 430 , and a rear housing 440 .

1) Description of the first opening 410

The first opening 410 is an opening provided on the left side of the housing 400 , and forms a passage through which the first flow passage 310 of the flow passage 300 is fluidly connected to the outside of the housing 400 . to provide. In the illustrated embodiment, the first opening 410 is formed to be elongated in the vertical direction on the left side of the housing 400 , but the position and shape thereof may be changed.

However, in any case, it is preferable that the position and shape of the first opening 410 be determined to correspond to the position and shape of the first flow path part 310 .

The first opening 410 may be completely opened or completely closed by the first flow path opening/closing part 312 . Also, the first opening 410 may be partially opened by the first flow passage opening/closing part 312 .

To this end, as described above, the first flow path opening/closing part 312 is movably provided on one side of the first opening 410 .

In the illustrated embodiment, the first flow path opening and closing part 312 is rotatably coupled to the upper side of the first opening 410 to open or close the first opening 410, but the first flow path opening and closing part 312 is the first A method of opening or closing the opening 410 may be changed.

In another embodiment, the first flow path opening/closing unit 312 may be opened or closed by sliding or folding the first opening 410 .

Opening and closing of the first opening 410 and the second opening 420 to be described later may be performed independently of each other. In addition, as will be described later, when the air cleaning module 10 according to an embodiment of the present invention is operated to perform various modes, the opening and closing of the first opening 410 is the opening and closing of the second opening 420 in a specific mode. can proceed accordingly.

The relationship between the opening and closing of the first opening 410 and the second opening 420 to be described later and the opening and closing of the first opening 410 and the second opening 420 to be described later in each mode will be described in detail later. .

2) Description of the second opening 420

The second opening 420 is an opening provided on the right side of the housing 400 , and forms a passage through which the second flow passage 320 of the flow passage 300 is fluidly connected to the outside of the housing 400 . to provide. In the illustrated embodiment, the second opening 420 is formed to be elongated in the vertical direction on the right side of the housing 400 , but the position and shape thereof may be changed.

However, in any case, it is preferable that the position and shape of the second opening 420 be determined to correspond to the position and shape of the second flow path part 320 .

The second opening 420 may be completely opened or completely closed by the second flow passage opening/closing part 322 . Also, the second opening 420 may be partially opened by the second flow passage opening/closing part 322 .

To this end, as described above, the second flow passage opening/closing part 322 is movably provided on one side of the second opening 420 .

In the illustrated embodiment, the second flow path opening and closing part 322 is rotatably coupled to the upper side of the second opening 420 to open or close the second opening 420, but the second flow path opening and closing part 322 is the second A method of opening or closing the opening 420 may be changed.

In another embodiment, the second flow passage opening/closing unit 322 may be opened or closed by sliding or folding the second opening 420 .

Opening and closing of the first opening 410 and the second opening 420 may be performed independently of each other. In addition, as will be described later, when the air cleaning module 10 according to an embodiment of the present invention is operated to perform various modes, the opening and closing of the second opening 420 is the opening and closing of the first opening 410 in a specific mode. can proceed accordingly.

The relationship between the opening and closing of the first opening 410 and the second opening 420 and the opening and closing of the first opening 410 and the opening and closing of the second opening 420 in each mode will be described later.

3) Description of the front housing 430 and the rear housing 440

Referring to FIG. 7 , the housing 400 according to the illustrated embodiment further includes a front housing 430 and a rear housing 440 .

The front housing 430 and the rear housing 440 support the combined blower fan 100 , the flow path division part 200 , and the flow path part 300 so that they can be stably maintained in a coupled state.

The shape of the front housing 430 and the rear housing 440 is preferably determined to correspond to the shape of the housing 400, and the blowing fan 100, the flow path division part 200 and the flow path part (200) coupled to the inside thereof. 300) is preferably provided to stably support.

(5) Description of the sensor unit 500

Referring back to FIGS. 1 and 2 , the air cleaning module 10 according to the illustrated embodiment includes a sensor unit 500 .

The sensor unit 500 detects the indoor situation in which the air cleaning module 10 is located, and transmits the corresponding information to the controller 600 to be described later, so that indoor air cleaning can be performed in various ways according to the indoor situation. do.

In the illustrated embodiment, the sensor unit 500 includes a motion sensor 510 and a dust sensor 520 , but may further include a temperature sensor (not shown), a humidity sensor (not shown), and the like.

In the illustrated embodiment, the sensor unit 500 is located on the upper side of the front side of the housing 400 , but its position may be changed to other positions capable of detecting indoor conditions. In addition, the sensor unit 500 may be provided on each side of the housing 400 .

1) Description of the motion sensor 510

The motion sensor 510 detects whether a person or an object in the vicinity of the air cleaning module 10 moves and its degree.

In the illustrated embodiment, the motion sensor 510 is located on the front side of the air cleaning module 10 , and will detect whether an object moves in front of the air cleaning module 10 .

Similarly, when the position of the motion sensor 510 is changed, the motion sensor 510 will detect whether an object at the position is moved.

As a result of the detection of the motion sensor 510 , when a movement of an object is detected, since a person or an animal is moving from the front side of the air cleaning module 10 , more dust generation can be expected.

In addition, as a result of the detection of the motion sensor 510 , when there is no movement of an object for a long time, it can be expected that more dust is accumulated on the floor.

The result detected by the motion sensor 510 is transmitted to the control unit 600 to be described later, and is utilized to select an operation method of the air cleaning module 10 . A detailed description of this process will be provided later.

2) Description of the dust sensor 520

The dust sensor 520 detects a concentration of dust around the air cleaning module 10 . The dust sensor 520 may include a fine dust sensor (not shown) for detecting the concentration of fine dust, a general dust sensor (not shown) for detecting the concentration of dust of a general size, and the like, so that the detection accuracy can be improved. have.

In the illustrated embodiment, the dust sensor 520 is located on the front side of the air cleaning module 10 , and will detect the dust concentration in the front of the air cleaning module 10 .

Similarly, when the position of the dust sensor 520 is changed, the dust sensor 520 will detect the dust concentration at that position.

As a result of the detection of the dust sensor 520 , when a large amount of fine dust is detected, it can be expected that the amount of dust floating in the indoor space is greater than that of the general size of dust.

In addition, when a large amount of dust of a general size is detected as a result of the detection of the dust sensor 520 , it may be expected that the amount of dust floating or deposited on the lower side or floor of the indoor space is greater than the fine dust.

The result detected by the dust sensor 520 is transmitted to the control unit 600 to be described later, and is used to determine the operation method of the air cleaning module 10 . A detailed description of this process will be provided later.

(6) Description of the control unit 600

Referring to FIG. 8 , the air cleaning module 10 according to an embodiment of the present invention further includes a control unit 600 .

The control unit 600 calculates an operation method of the air cleaning module 10 by using the motion information and dust information detected by the motion sensor 510 and the dust sensor 520 of the sensor unit 500 .

In one embodiment, the control unit 600 may be provided with a microprocessor, CPU, or the like.

In order to calculate the operation method of the air cleaning module 10 using the information detected by the sensor unit 500 and to operate the air cleaning module 10 correspondingly, the control unit 600 includes the sensor unit 500, It is electrically connected to the blowing fan 100 and the flow path unit 300 to transmit/receive information to and from each other.

The control unit 600 is provided in the air cleaning module 10 , respectively. A detailed description thereof will be provided later.

The control unit 600 includes a blowing fan control module 610 , a flow path control module 620 , a motion calculation module 630 , and an air quality calculation module 640 .

1) Description of the blowing fan control module 610

The blowing fan control module 610 calculates whether the power of the blowing fan 100 is applied, whether it rotates, a rotation speed, etc. (hereinafter referred to as "blowing fan 100 control information").

The reference information for controlling the blowing fan 100 is directly input by a user, or a calculation result value of the motion calculation module 630 to be described later using motion information detected by the motion sensor 510, and the dust sensor 520. The calculation result value of the air quality calculation module 640 which will be described later using the detected dust information is used.

The blowing fan 100 control information calculated by the blowing fan control module 610 is transmitted to the blowing fan 100 , and the blowing fan 100 is operated according to the calculated blowing fan 100 control information.

2) Description of the flow path control module 620

The flow path control module 620 is configured to form one or more flow paths so that clean air can be discharged through any one or more of the first flow path part 310 and the second flow path part 320 of the flow path part 300 . Information (hereinafter, referred to as "channel 300 control information") is calculated.

Reference information for controlling the flow path unit 300 is directly input by a user, or an operation result value of the motion calculation module 630 to be described later using motion information detected by the motion sensor 510, or the dust sensor 520. The calculation result value of the air quality calculation module 640 which will be described later using the detected dust information is used.

Specifically, the flow path control module 620 calculates the number of flow paths through which the clean air is to be discharged, and determines whether at least one of the first flow path unit 310 and the second flow path unit 320 is opened.

Further, it is determined whether at least one of the first flow path opening/closing part 312 and the second flow path opening/closing part 322 moves according to the flow path part determined to be opened, and the first flow path opening/closing part 312 according to the discharge direction or angle of the clean air. ) and the degree of movement of the second flow path opening/closing unit 322 , that is, the positions of each opening/closing unit 312 and 322 are calculated.

Whether or not any one or more of the first flow path unit 310 and the second flow path unit 320 calculated by the flow path control module 620 is opened and closed, and accordingly, the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 are closed. Operation status and location, and control information of the flow path unit 300 are transmitted to the flow path unit 300 , and the flow path unit 300 operates according to the flow path unit 300 control information calculated by the flow path unit control module 620 . do.

3) Description of the motion calculation module 630

The motion calculation module 630 calculates reference information for calculating the blowing fan 100 control information and the flow path unit 300 control information by using the motion information detected by the motion sensor 510 .

Hereinafter, a calculation process of reference information for the motion calculation module 630 to generate the blowing fan 100 control information and the flow path unit 300 control information according to the detection result of the motion sensor 510 will be described as an example.

Specifically, when a movement of an object is detected as a result of the detection of the motion sensor 510 , since a person or an animal is moving from the front side of the air cleaning module 10 , more dust generation can be expected.

In this case, reference information for rotating the blowing fan 100 at a high speed is calculated, and the opening and closing of the first flow path part 310 and the second flow path part 320 correspond to the distance of the position where the movement of the object is sensed. Calculate whether or not the discharge direction of clean air.

In addition, as a result of the detection of the motion sensor 510 , when there is no movement of an object for a long time, it can be expected that more dust is accumulated on the floor.

In this case, the reference information for rotating the blowing fan 100 at a high speed is calculated, and the first flow path part 310 and the second flow path part 320 are calculated according to the distance of the position where the movement of the object is sensed. It calculates whether the valve is open or not and the discharge direction of clean air.

Of course, the rotation speed of the blowing fan 100 according to the detection result of the motion sensor 510, etc. can be changed. For example, the efficiency of indoor air cleaning may be improved by operating the blowing fan 100 at a low speed for a long time.

Similarly, the flow path part 300 to be opened and closed and its direction are also changed to correspond to various modes as will be described later, thereby improving the efficiency of indoor air cleaning.

The reference information calculated by the motion calculation module 630 is transmitted to the blowing fan control module 610 and the flow path unit control module 620, respectively, and calculates the blowing fan 100 control information and the flow path unit 300 control information, respectively. It is used as reference data for

4) Description of the air quality calculation module 640

The air quality calculation module 640 calculates reference information for calculating the blowing fan 100 control information and the flow path unit 300 control information by using the dust information detected by the dust sensor 520 .

Hereinafter, a calculation process of reference information for the air quality calculation module 640 to generate the blowing fan 100 control information and the flow path unit 300 control information according to the detection result of the dust sensor 520 will be described as an example.

Specifically, as a result of the detection of the dust sensor 520 , when the concentration of fine dust is greater than the concentration of dust of a general size, it may be expected that the indoor air is mainly polluted by the fine dust.

In this case, the fine dust is more likely to be floating in the indoor space than the dust of a general size, and it can be determined that the fine dust can be removed even when air is discharged at a low speed.

Therefore, the reference information for rotating the blowing fan 100 at a low speed is calculated, and the discharge direction is calculated so that the air discharged from the flow path unit 300 is directed toward the middle or upper side so that the air discharged from the flow path part 300 can face the space part instead of the floor of the room. do.

Also, as a result of the detection of the dust sensor 520 , when the concentration of dust of a general size is greater than that of fine dust, it may be expected that the indoor air is mainly polluted by dust of a general size.

In this case, it can be determined that dust of a general size is more likely to float in the lower part of the indoor space or accumulate on the floor than fine dust, and can be removed more effectively when air is discharged at a high speed.

Therefore, the reference information for rotating the blowing fan 100 at a high speed is calculated, and the discharge direction is calculated so that the air discharged from the flow path part 300 is directed toward the middle or lower side, or the floor, not the space part of the room. .

Of course, the rotation speed of the blowing fan 100 according to the detection result of the dust sensor 520 may be changed. For example, the efficiency of indoor air cleaning may be improved by operating the blowing fan 100 at a low speed for a long time or at a high speed for a short time.

Similarly, the flow path part 300 to be opened and closed and its direction are also changed to correspond to various modes as will be described later, thereby improving the efficiency of indoor air cleaning.

The reference information calculated by the air quality calculation module 640 is transmitted to the blowing fan control module 610 and the flow path control module 620, respectively, and provides the blowing fan 100 control information and the flow path unit 300 control information, respectively. It is used as reference data for calculation.

2. Description of the air purifier (1)

Hereinafter, the air purifier 1 according to an embodiment of the present invention will be described in detail with reference to FIG. 9 .

A plurality of air cleaning modules 10 according to the illustrated embodiment are provided and stacked in the vertical direction, thereby configuring the air cleaner 1 .

Referring to (a) of FIG. 9 , as a case in which one air cleaning module 10 is provided, the air cleaner 1 is shown when used in a small square or narrow room.

Referring to FIG. 9B , the air cleaner 1 is illustrated when two air cleaning modules 10 are provided and used in a medium-sized or medium-sized room.

Referring to FIG. 9C , the air cleaner 1 is illustrated when three air cleaning modules 10 are provided and used in a large square or large-sized room.

In the illustrated embodiment, the air cleaning module 10 is provided up to three in total, but the number is changeable, and the air cleaner 1 is stacked vertically or continuously in the left and right directions as in the illustrated embodiment. could be

Of course, when the plurality of air cleaning modules 10 are continuous in the left and right directions to form the air cleaner 1 , the position of the flow path unit 300 should be changed accordingly.

The plurality of air cleaning modules 10 may each be operated independently. That is, each air cleaning module 10 independently includes each of the above-described configurations, so that the blowing fan 100 , the flow passage 400 , the sensor 500 and the like of each air cleaning module 10 are independent of each other. can work with

In particular, since the plurality of air cleaning modules 10 are stacked in the vertical direction, motion information and dust information can be sensed for each height, and accordingly, the height of the clean air discharged from the flow path unit 300 can be configured in various ways. Therefore, the air purifier 1 can be controlled in various ways by the above-described control unit 600, a detailed description thereof will be described later.

Alternatively, in the plurality of air cleaning modules 10 constituting the air cleaner 1, the discharge direction of the clean air and the rotation speed of each blowing fan 100 may be controlled to be dependent on each other.

3. Description of the operating mode of the air purifier (1)

Hereinafter, a method of controlling the air purifier 1 according to the illustrated embodiment will be described with reference to FIGS. 10 to 13 .

10 to 13 each show an operating mode of the air purifier 1 according to an embodiment of the present invention. 13 shows a short-distance cleaning mode and a short-distance intensive cleaning mode, respectively.

In the illustrated embodiment, the air purifier 1 is configured by stacking two to three air cleaning modules 10, respectively, in the vertical direction, but the number can be changed as described above.

Each of the modes described below may be input by a user through a separate input unit (not shown) or may be automatically performed according to the condition of the indoor air sensed through the sensor unit 500 .

(1) Description of normal mode

Referring to FIG. 10 , a process in which the air purifier 1 according to the illustrated embodiment operates in a normal mode is illustrated.

The normal mode is a mode for maintaining an average or normal indoor air quality.

First, the blowing fan control module 610 controls the blowing fan 100 to rotate. In this case, the rotation speed of the blowing fan 100 may be arbitrarily determined, such as determined according to information sensed by the sensor unit 500 or determined according to a user's input.

Also, the flow path control module 620 moves at least one of the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 .

Specifically, since the normal mode is a case in which the air cleaning module 10 is operated without a separate change, the first flow path unit 310 and the second flow path unit 320 can discharge clean air. Both the flow path opening/closing part 312 and the second flow path opening/closing part 322 are opened.

In this case, the opening degree of the first flow passage opening/closing part 312 and the second flow passage opening/closing part 322 may be adjusted to be different from each other.

In addition, the direction of the clean air discharged from the first flow path part 310 and the second flow path part 320 is also spread in a horizontal direction without any limitation.

As described above, each air cleaning module 10 includes a first flow path part 310 and a second flow path part 320 on the left and right, respectively, so that clean air is discharged in the left and right directions of the air cleaning module 10 . .

In the case of the normal mode, since a separate control process according to external factors according to height and the like is unnecessary, the air cleaning module 10 may be provided as one to configure the air cleaner 1 . Alternatively, the normal mode may also be operated according to information sensed by the sensor unit 500 .

In addition, a plurality of such air cleaning modules 10 are provided and stacked in the vertical direction, and two first flow passages 310 for discharging clean air to the left and two second flow passages for discharging clean air to the right are provided. 320 is provided, and clean air is discharged from a total of four positions.

The air cleaning module 10 located on the lower side is provided with a separate holder and can be supported on the indoor floor, and the air cleaning module 10 located on the upper side is provided with a coupling member (not shown) and is located on the lower side. It can be stably combined with the air cleaning module 10 .

Accordingly, when the air purifier 1 is operated in the normal mode, it is possible to perform air cleaning according to the average indoor air quality, and thus, it is possible to maintain a generally required indoor air quality while minimizing power consumption.

(2) Description of rapid cleaning mode

Referring to FIG. 11 , a process in which the air purifier 1 is operated in the rapid cleaning mode according to the illustrated embodiment is illustrated.

The quick clean mode is a mode for quickly improving indoor air quality.

First, the blowing fan control module 610 controls the blowing fan 100 to rotate. In this case, the rotation speed of the blowing fan 100 may be arbitrarily determined, such as determined according to information sensed by the sensor unit 500 or determined according to a user's input.

Preferably, the blowing fan control module 610 may control the rotation speed of the blowing fan 100 to be the maximum to maintain the amount of clean air discharged to the maximum.

Also, the flow path control module 620 moves at least one of the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 .

Specifically, since the rapid cleaning mode is a mode for discharging clean air to the entire indoor space, the first flow path opening/closing unit ( 312) and the second flow path part 322 are both open.

In this case, the opening degree of the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 may be adjusted to be different from each other. ), it is desirable to open it so that the amount of clean air discharged is maximized.

As shown in (a) of FIG. 11 , the air cleaning module 10 in this mode includes the air cleaning module 11 located at the uppermost side, the air cleaning module 10 located in the middle, and the air cleaning module 10 located at the lower side. It is divided into an air cleaning module (12).

At this time, the discharge direction is controlled so that the clean air discharged from the air cleaning module 11 located at the uppermost side is discharged toward the upper side, and the clean air discharged from the air cleaning module 10 located in the middle is discharged horizontally. The discharge direction is controlled, and the discharge direction is controlled so that the clean air discharged from the air cleaning module 12 located at the lower side is discharged toward the lower side.

That is, the discharge direction of the clean air is determined according to the position of each of the air cleaning modules 10 , 11 and 12 constituting the air cleaner 1 .

Alternatively, the discharge direction of the clean air discharged from the air cleaning module 10 located in the middle may be controlled to be discharged toward the upper side or the lower side in addition to the horizontal direction.

In addition, as shown in (b) of FIG. 11 , the clean air discharged from each of the air cleaning modules 10 , 11 , and 12 may be discharged toward the front side, the left and right sides, and the rear side.

Therefore, when the air purifier 1 is operated in the rapid cleaning mode, the clean air discharged from the air purifier 1 is discharged in all directions of the three-dimensional coordinate system, so that the indoor air quality can be improved at a rapid rate.

(3) Description of remote cleaning mode

Referring to FIG. 12 , a process of operating the air purifier 1 in the remote cleaning mode according to the illustrated embodiment is illustrated.

The long-distance cleaning mode is a mode for cleaning the air of an area located far from the air purifier 1 .

First, the blowing fan control module 610 controls the blowing fan 100 to rotate. In this case, the rotation speed of the blowing fan 100 may be arbitrarily determined, such as determined according to information sensed by the sensor unit 500 or determined according to a user's input.

Preferably, the blowing fan control module 610 may control the rotation speed of the blowing fan 100 to be the maximum to maintain the amount of clean air discharged to the maximum.

Also, the flow path control module 620 moves at least one of the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 .

Preferably, both the first flow passage opening/closing part 312 and the second flow passage part 322 are opened so that clean air can be discharged from both the first flow passage part 310 and the second flow passage part 320 .

In this case, the opening degree of the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 may be adjusted to be different from each other. ), it is desirable to open it so that the amount of clean air discharged is maximized.

As shown in (a) of FIG. 12 , the air cleaning module 10 in this mode includes the air cleaning module 11 located at the uppermost side, the air cleaning module 10 located in the middle, and the lower side. It is divided into an air cleaning module (12).

At this time, the discharge direction is controlled so that the clean air discharged from the air cleaning module 11 located at the uppermost side is discharged horizontally, and the clean air discharged from the air cleaning module 10 located in the middle is discharged toward the upper side. The discharge direction is controlled, and the discharge direction is controlled so that the clean air discharged from the air cleaning module 12 located at the lower side is also discharged toward the upper side.

Specifically, since the remote cleaning mode is a mode for forming a flow in which the clean air largely circulates in the indoor space to purify the air in the area located far from the air purifier 1, each air cleaning module 10, 11, 12) is controlled so that all of the clean air discharged is directed upward.

Alternatively, the discharge direction may be controlled so that the clean air discharged from the air cleaning module 11 located at the upper side is also discharged toward the upper side rather than the horizontal direction.

In addition, as shown in (b) of FIG. 12 , the clean air discharged from each air cleaning module 10 , 11 , and 12 may be discharged only toward the front side.

In this mode, since it is preferable that the flow of the clean air discharged from the air purifier 1 increases, the direction of the discharged clean air is concentrated toward the front side to induce easy formation of the flow and enlargement of the flow.

Therefore, when the air purifier 1 is operated in the remote cleaning mode, the clean air discharged from the air purifier 1 is discharged toward the upper side of the front, and a large flow circulating the indoor space is formed, so that it is located at a remote location. The cleaning of the air in the area to be used can be carried out.

(4) Description of short-distance cleaning mode and short-distance intensive cleaning mode

Referring to FIG. 13 , a process in which the air purifier 1 according to the illustrated embodiment is operated in the short-distance cleaning mode or the short-distance intensive cleaning mode is illustrated.

The short-distance cleaning mode or the short-distance intensive cleaning mode is a mode for cleaning the air of an area located in a short distance from the air purifier 1 .

First, the blowing fan control module 610 controls the blowing fan 100 to rotate. In this case, the rotation speed of the blowing fan 100 may be arbitrarily determined, such as determined according to information sensed by the sensor unit 500 or determined according to a user's input.

Preferably, the blowing fan control module 610 may control the rotation speed of the blowing fan 100 to be the maximum to maintain the amount of clean air discharged to the maximum.

Also, the flow path control module 620 moves at least one of the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 .

Preferably, both the first flow passage opening/closing part 312 and the second flow passage part 322 are opened so that clean air can be discharged from both the first flow passage part 310 and the second flow passage part 320 .

At this time, the opening degree of the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 may be adjusted to be different from each other. ), it is desirable to open it so that the amount of clean air discharged is maximized.

As shown in FIG. 13 , the air cleaning module 10 in this mode includes an air cleaning module 11 located at the uppermost side, an air cleaning module 10 located in the middle, and an air cleaning module located at the lower side ( 12).

At this time, the discharge direction is controlled so that the clean air discharged from the air cleaning module 11 located at the uppermost side is discharged downward, and the clean air discharged from the air cleaning module 10 located in the middle is also discharged downward. The discharge direction is controlled so as to be possible, and the discharge direction is controlled so that the clean air discharged from the air cleaning module 12 located at the lower side is discharged horizontally or toward the lower side.

Specifically, since the short-distance cleaning mode is a mode for forming a flow in which the clean air circulates small in the indoor space in order to purify the air in an area located in a short distance from the air purifier 1, each air cleaning module 10, 11, 12) is controlled so that all of the clean air discharged is directed downward.

Alternatively, the discharge direction may be controlled so that the clean air discharged from the air cleaning module 12 located at the lower side is also discharged toward the lower side rather than the horizontal direction.

In addition, there is a difference in the rotational speed of the blowing fan 100 of each air cleaning module 10 , 11 , and 12 in the short-distance intensive cleaning mode for intensively cleaning an area located in a short distance from the air purifier 1 .

That is, by controlling the rotation speed of the blowing fan 100 of the air cleaning module 12 located on the lower side to be higher than the rotation speed of the blowing fan 100 of the air cleaning module 11 located on the upper side, The dust accumulated on the floor can be removed more effectively.

Specifically, by discharging clean air at a faster speed from the air cleaning module 12 located on the lower side, the dust accumulated on the floor in the vicinity is removed as if it is swept away by a blower, etc., and then the air located in the middle The clean air discharged from the cleaning module 10 and the air cleaning module 11 located on the upper side follows, catches the removed dust, flows through the indoor space, and flows into the air cleaner 1 to perform air cleaning.

Accordingly, when the air purifier 1 is operated in the short-distance cleaning mode, the clean air discharged from the air purifier 1 is discharged downward, removing dust from the lower side of the indoor space and forming a small flow circulating the indoor space. Therefore, it is possible to purify the air of a region located in a short distance.

Furthermore, when the air purifier 1 is operated in the short-distance intensive cleaning mode, the speed of the clean air discharged from the air purifier 1 is different depending on the discharge height, that is, the air cleaning module 10 located at the lower side. Since the speed of the clean air discharged from the air conditioner is controlled the fastest, dust removal and air cleaning can be performed more effectively.

Therefore, the air purifier 1 according to the embodiment of the present invention can maximize the efficiency of indoor air cleaning according to the purpose through various modes of controlling the plurality of air cleaning modules 10 independently or correspondingly to each other. can

4. Description of the process in which the air purifier 1 is controlled according to the information detected by the sensor unit 500

The air cleaning module 10 and the air cleaner 1 including the same according to an embodiment of the present invention change the discharge method of the clean air according to the motion information and the dust information detected by the sensor unit 500, so that the indoor space It is possible to purify the air according to the situation.

Hereinafter, a method of controlling the air purifier 1 according to an embodiment of the present invention will be described in detail with reference to FIGS. 14 and 15 .

In the following description, the sensor unit 500 may detect any one or more of motion information and dust information, and preferably, both types of information.

(1) Description of the process in which the air purifier 1 is controlled according to motion information (S100)

Referring to FIG. 14 , first, the sensor unit 500 detects at least one of motion information and dust information ( S110 ).

As described above, the sensor unit 500 includes a motion sensor 510 and a dust sensor 520 to detect both motion information and dust information. A process in which the air purifier 1 is controlled using the detected motion information will be mainly described.

Next, the motion calculation module 630 uses the motion information detected by the sensor unit 500 to determine the rotation speed of the blowing fan 100 ; the direction of the fluid discharged from the first flow path part 310 and the second flow path part 320 ; and the positions of the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 are calculated ( S120 ).

That is, as described above, the motion calculation module 630 calculates reference information for generating the blowing fan 100 control information and the flow path unit 300 control information using the motion information detected by the motion sensor 510 . .

At this time, the blowing fan 100 control information includes information on whether the blowing fan 100 rotates and a rotation speed, and the flow path part 300 control information includes the first flow path part 310 and the second flow path part ( 320), the direction of the discharged fluid, that is, clean air; and positions of the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 .

At this time, the method of generating the control information of the blowing fan 100 and the control information of the flow path unit 300 by the motion calculation module 630 may go through the same process as described above.

The blowing fan 100 control information and the flow path unit 300 control information calculated by the motion calculation module 630 are transmitted to the blowing fan 100 control module 610 and the flow path unit control module 620 , respectively.

First, the blowing fan control module 610 controls the blowing fan 100 to rotate according to the calculated rotation speed of the blowing fan 100 ( S130 ).

That is, the blowing fan control module 610 controls the blowing fan 100 according to the blowing fan 100 control information received from the motion calculation module 630 .

In addition, the flow path control module 620 includes the calculated directions of the fluid discharged from the first flow path unit 310 and the second flow path unit 320 ; and the first flow path part 310 , the second flow path part 320 , the first flow path opening/closing part 312 , and the second flow path opening/closing part 322 according to the positions of the first flow path opening/closing part 312 and the second flow path opening/closing part 322 . ) is controlled (S140).

That is, the flow path part control module 620 controls the flow path part 300 according to the flow path part 300 control information received from the motion calculation module 630 .

Therefore, according to the method of controlling the air purifier 1 according to the illustrated embodiment, since the generation amount of dust and the accumulation amount of dust are predicted according to the movement of an object, and air cleaning is performed accordingly, the cleaning process of indoor air is can be performed effectively.

(2) Description of the process in which the air purifier 1 is controlled according to the dust information (S200)

Referring to FIG. 15 , first, the sensor unit 500 detects at least one of motion information and dust information ( S210 ).

As described above, the sensor unit 500 includes a motion sensor 510 and a dust sensor 520 to detect both motion information and dust information. In this embodiment, the dust sensor 520 is A process in which the air purifier 1 is controlled using the detected dust information will be mainly described.

Next, the air quality calculation module 640 uses the dust information detected by the sensor unit 500 to determine the rotation speed of the blowing fan 100; the direction of the fluid discharged from the first flow path part 310 and the second flow path part 320 ; and the positions of the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 are calculated ( S220 ).

That is, as described above, the air quality calculation module 640 calculates reference information for generating the blowing fan 100 control information and the flow path unit 300 control information using the dust information detected by the dust sensor 520 . do.

At this time, the blowing fan 100 control information includes information on whether the blowing fan 100 rotates and a rotation speed, and the flow path part 300 control information includes the first flow path part 310 and the second flow path part ( 320), the direction of the discharged fluid, that is, clean air; and positions of the first flow path opening/closing unit 312 and the second flow path opening/closing unit 322 .

At this time, the method of generating the air quality calculation module 630 control information of the blowing fan 100 and the flow path unit 300 control information may go through the same process as described above.

The blowing fan 100 control information and the flow path unit 300 control information calculated by the air quality calculation module 640 are transmitted to the blowing fan 100 control module 610 and the flow path unit control module 620 , respectively.

First, the blowing fan control module 610 controls the blowing fan 100 to rotate according to the calculated rotation speed of the blowing fan 100 ( S230 ).

That is, the blowing fan control module 610 controls the blowing fan 100 according to the blowing fan 100 control information received from the air quality calculation module 630 .

In addition, the flow path control module 620 includes the calculated directions of the fluid discharged from the first flow path unit 310 and the second flow path unit 320 ; and the first flow path part 310 , the second flow path part 320 , the first flow path opening/closing part 312 , and the second flow path opening/closing part 322 according to the positions of the first flow path opening/closing part 312 and the second flow path opening/closing part 322 . ) is controlled (S240).

That is, the flow path part control module 620 controls the flow path part 300 according to the flow path part 300 control information received from the air quality calculation module 630 .

Therefore, according to the method of controlling the air purifier 1 according to the illustrated embodiment, since the accumulation or floating position is predicted according to the size of the higher concentration of dust and air cleaning is performed accordingly, the cleaning process of indoor air is can be performed effectively.

Although described above with reference to the preferred embodiment of the present invention, those of ordinary skill in the art can variously modify and change the present invention within the scope without departing from the spirit and scope of the present invention described in the claims below. You will understand that you can.

1: Air purifier
10: air cleaning module
11: upper air cleaning module
12: lower air cleaning module
100: blow fan
110: motor
200: euro division
210: first flow path coupling groove
220: second flow path coupling groove
300: Euro
310: first flow path part
312: first flow path opening and closing part
320: second flow path part
322: second flow path opening and closing part
400: housing
410: first opening
420: second opening
430: front housing
440: rear housing
500: sensor unit
510: motion sensor
520: dust sensor
600: control unit
610: blowing fan control module
620: flow path control module
630: motion calculation module
640: air quality calculation module
A: Inflow direction of outside air
B: discharge direction of clean air
C: the central boundary of the housing

Claims (5)

An air purifier comprising an air purifying module (10), comprising:
The air cleaning module 10,
a double-suction blower fan 100 configured to suck in outside air from both directions of the rotating shaft and discharge it in a direction perpendicular to the rotating shaft;
A plate-shaped member including a hollow in which the blowing fan 100 is located and disposed in a direction perpendicular to the rotation axis of the blowing fan 100 between both sides of the blowing fan 100 through which the outside air is sucked, between both ends of the blowing fan 100 through which the outside air is sucked, a flow path dividing part 200 mounted so that both sides of the blowing fan 100 protrude;
The first flow path part 310 located on one side of the flow path division unit 200 and the other side opposite to the blowing fan 100 with respect to the one side of the flow path division unit 200 are located on the other side a flow path part 300 including a second flow path part 320 ; and
and a housing 400 accommodating the blowing fan 100, the flow path dividing part 200 and the flow path receiving part 300 therein,
The first flow path part 310 and the second flow path part 320 are respectively formed to discharge air in opposite directions,
The housing 400 is located on one side, and is located on the first opening 410 and the other side that fluidly connect the first flow path part 310 and the outside of the housing 400, and a second opening 420 connecting the second flow path 320 and the outside of the housing 400 in a fluid communication manner;
The first flow path part 310 communicates with the first opening 410 with the air discharge part of the blower fan 100 protruding to one side of the flow path dividing part 200 , the flow path dividing part 200 . is located in
The second flow path part 320 communicates with the air discharge part of the blower fan 100 protruding to the other side of the flow path division part 200 with the second opening 420 . is located in
In both directions of the blowing fan 100, the outside air is discharged to the outside through at least one of the first flow path part 310 and the second flow path part 320,
air cleaner.
According to claim 1,
a first flow path opening/closing part 312 provided at one side of the first opening 410 and configured to open and close the first opening 410; and
a second flow passage opening/closing part 322 provided at one side of the second opening 420 and configured to open and close the second opening 420; further comprising,
The first opening 410 and the second opening 420 are disposed to face each other in the housing 400,
air cleaner.
3. The method of claim 2,
The first flow path opening and closing part 312 and the second flow path opening and closing part 322 are operated independently,
air cleaner.
According to claim 1,
The flow path dividing unit 200,
a first flow passage coupling groove 210 formed on the one side of the flow passage dividing unit 200; and
A second flow passage coupling groove 220 formed on the other side opposite to the blowing fan 100 with respect to the one side of the flow passage dividing unit 200; further comprising,
The first flow passage 310 is detachably coupled to the first flow passage coupling groove 210 , and the second flow passage 320 is detachably coupled to the second flow passage coupling groove 220 . felled,
air cleaner.
According to claim 1,
The discharge port of the first flow path part 310 is installed in the first opening 410 , the discharge port of the second flow path part 320 is installed in the second opening 420 , and the first flow path part ( The inlet of the 310 and the inlet of the second flow path 320 are installed to communicate with the blowing fan 100, respectively, so that the outside air sucked by the blowing fan 100 flows through the first opening 410 and characterized in that it is discharged to the outside through the second opening 420,
air cleaner.

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