KR102379754B1 - Air cleaning apparatus and a method controlling the same - Google Patents

Abstract

This embodiment relates to an air purifier and a control method therefor.
The air purifier according to this embodiment includes a control unit for controlling selective operation of the first and second air cleaning modules or the flow control device, wherein the control unit operates the second air cleaning module and the flow control device together when the rotation speed of the circulation fan may be controlled to be equal to or greater than the rotation speed of the second fan.

Description

Air cleaning apparatus and a method controlling the same

The present invention relates to an air purifier and a method for controlling the same.

An air purifier is understood as a device that sucks in polluted air, purifies it, and then discharges the purified air. For example, the air purifier may include a blower for introducing external air into the inside of the air purifier and a filter capable of filtering dust or bacteria in the air.

In general, an air purifier is configured to purify an indoor space such as a home or office. According to the conventional air purifier, there is a problem in that its capacity is limited, so that it is limited to purify the air of the entire indoor space. Therefore, while the air around the air purifier can be purified, there is a problem in that it is difficult to purify the air in a space far away from the air purifier.

In order to solve this problem, efforts have been made to improve the performance of the fan provided in the air purifier, but as the fan blown amount increases, the noise generated from the fan increases, thereby reducing the reliability of the product.

After all, due to the limited capacity of the air purifier, the user has the inconvenience of having to purify the air in a desired space while moving the air purifier.

In relation to the conventional air purifier, the present applicant has disclosed the following prior literature.

1. Publication number (disclosure date): KR10-2012-0071992 (July 3, 2012)

2. Title of invention: air purifier

According to the preceding document, the main body of the air purifier is provided with air purifying parts such as a fan and a filter inside a case having a substantially rectangular parallelepiped shape. In addition, the air intake port is formed on the side and the lower portion of the main body of the air purifier, the air outlet is formed on the upper portion of the main body.

According to this configuration, there is a problem in that the suction capacity is reduced because the contaminated air is sucked in a limited direction, that is, from the side and below, based on the air purifier. And, the corner portion of the case having a rectangular parallelepiped shape acts as a structural resistance that prevents the intake of air.

In addition, since the purified air inside the air purifier is discharged only in one direction, that is, upward, the air around the air purifier can be purified, whereas the purified air cannot flow to a space far away from the air purifier, There was a problem in that the air cleaning function was limited.

In addition, since only one blowing fan is provided inside the main body of the air purifier, there is a problem in that the blowing capacity is limited.

An object of the present embodiment is to provide an air purifier capable of controlling the amount of discharged air according to the size of a space to be cleaned (hereinafter referred to as a clean space) in order to solve the above problems. In particular, an object of the present invention is to provide an air purifier in which a plurality of modules can be independently driven based on a required amount of air purifying.

Another object of the present invention is to provide an air purifier capable of determining an air pollution level (or air cleanliness level) through a sensor device and selectively driving the plurality of modules based on the determined air pollution level. In particular, an object of the present invention is to provide an air purifier capable of increasing the number of operating modules as the air pollution degree increases.

Another object of the present invention is to provide an air purifier that is provided with a plurality of operation modes and can control operation according to a user's preference. In particular, an object of the present invention is to provide an air purifier capable of easily harmonizing a clean space through a manual operation mode, an automatic operation mode, and a sub-module intensive operation mode.

Another object of the present invention is to provide an air purifier capable of adjusting the rotation speed of each fan in order to reduce noise generated by the fans provided in each of the plurality of modules.

Another object of the present embodiment is to provide an air purifier in which air discharged from the air purifier is discharged in various directions and can reach a long distance. In particular, to provide an air purifier capable of easily discharging airflow in the upward, forward and left and right directions around the air purifier, so that air can be easily discharged toward the surrounding space even when a occupant is sitting or standing. do.

The air purifier according to this embodiment includes a control unit for controlling selective operation of the first and second air cleaning modules or the flow control device, wherein the control unit operates the second air cleaning module and the flow control device together In this case, the rotation speed of the third fan may be controlled to be greater than or equal to the rotation speed of the second fan.

The operation mode includes a single mode in which the first air cleaning module is operated independently.

The operation mode includes a dual mode in which the first and second air cleaning modules are operated together.

The operation mode includes a circulation mode in which the first and second air cleaning modules and the flow control device are operated together.

The input unit includes an air volume input unit capable of inputting an air volume.

In the dual mode, the controller may control the rotation speed N1 ′ of the first fan to be greater than the rotation speed N1 of the second fan.

In the dual mode, the controller may control the rotation speed N1 ″ of the third fan to correspond to the rotation speed N1 of the second fan 260 .

The rotation speed N1 ″ of the third fan may be the same as the rotation speed N1 of the second fan 260 .

In the circulation mode, the controller may control the rotation speed N2'' of the third fan to be equal to or higher than the rotation speed N2 of the second fan.

In the circulation mode, the controller may control the rotation speed N2' of the first fan to be greater than the rotation speed N2 of the second fan.

The operation mode includes a manual operation mode in which a device to be operated and an air volume can be selected from among the first and second air cleaning modules and the flow control device.

The operation mode includes an automatic operation mode in which a device to be operated is determined among the first and second air cleaning modules and the flow control device according to the degree of pollution detected by the sensor device.

A partition plate disposed between the first air cleaning module and the second air cleaning module is further included.

The first and second fans and the circulation fan may be positioned on the same longitudinal axis.

A control method of an air purifier according to another aspect includes operating the lower air purifying module, the upper air purifying module, and the flow control device when a circulation mode is selected among operation modes, wherein the circulation mode is performed. In this case, the rotation speed of the first blowing fan may be greater than the rotation speed of the second blowing fan.

When the circulation mode is performed, the rotational speed of the third blowing fan may be greater than or equal to the rotational speed of the second blowing fan.

When the dual mode is selected among the operation modes, the lower air cleaning module and the upper air cleaning module may be operated.

When the dual mode is performed, the rotation speed of the first blowing fan may be greater than the rotation speed of the second blowing fan.

When the single mode is selected among the operation modes, the lower air cleaning module is operated, and the rotational speed of the first blowing fan may be adjusted according to the input air volume.

According to this embodiment, a plurality of modules including an air cleaning module and a flow control device capable of discharging the purified air that has passed through the air cleaning module to a long distance are provided, and the size of the clean space or the desired amount of air cleaning is provided. Accordingly, since the plurality of modules can be selectively driven, air cleaning efficiency is improved and user satisfaction is increased.

In addition, since a plurality of operation modes capable of controlling the operation of the air purifier are set, and any one of the plurality of operation modes may be determined according to a user's preference, user convenience may be increased.

In particular, the plurality of operation modes include a manual operation mode in which the user can select operation conditions, that is, the number of modules to be driven, and the air volume, and the user selects the manual operation mode to adjust the air cleaning amount or air cleaning speed. It has the advantage of being able to directly control the desired value.

And, the plurality of operation modes include an automatic operation mode in which the operation conditions can be determined based on the air pollution degree, and the type or number of modules to be driven and the air volume are automatically adjusted according to the level of the air pollution degree. Therefore, there is an advantage that the air cleaning operation can be efficiently performed according to the characteristics of the clean space.

In addition, the air purifier includes a dust sensor or a gas sensor, so that the level related to the air pollution degree can be easily determined.

In addition, the upper discharge of the air may be guided through the upper module, and the front discharge of the air may be guided by the flow control device provided on the upper side of the upper module. And, while the flow control device rotates, the discharge of air in the left and right directions may be guided. As a result, the air discharge is guided in various directions based on the air purifier, and the discharge air flow can be formed a long distance from the air purifier, so that the air cleaning function of the indoor space can be improved. In addition, there is an advantage that the discharge air flow can be easily generated toward the surrounding space even when the interior person is sitting or standing.

In addition, since a third fan is provided in the flow control device, the air flowing through the second blower can be discharged by adding a flow force of the third fan to the air. Accordingly, since a strong discharge airflow can be generated, there is an effect that the airflow can reach a location far away from the air purifier.

In addition, since a plurality of modules are provided, there is an advantage that the blowing capacity of the air purifier can be improved. In addition, independent air flows are generated through a plurality of air cleaning modules, and it is possible to prevent a phenomenon in which the air flows interfere with each other, thereby improving the air flow performance.

In addition, the effect of minimizing the resistance acting on the discharged air flow and reducing the noise generated from the fan by controlling the rotation speed of the fan provided in each operated module according to the module operated among the plurality of modules appear.

In particular, when the flow regulating device and the upper module operate together, that is, when the third fan drives and the second fan of the upper module drives with the flow regulating device in the upwardly protruding second position, the second fan The rotation speed of the second fan may be controlled to be maintained below the rotation speed of the third fan. In this case, the tendency of the air to be discharged upward is small and the tendency to be discharged toward the front upper side or the rear upper side through the flow control device can be increased, so that the discharged air can reach a long distance from the air purifier. .

And, the lower module and the upper module can be controlled independently or selectively. That is, only the lower module may be operated, only the upper module may be operated, or the lower module and the upper module may be operated together. When the upper and lower modules are operated together, the rotation speed of the first fan provided in the lower module may be controlled to be greater than the rotation speed of the second fan provided in the upper module.

At least some of the air discharged from the lower module may be sucked back into the suction unit of the upper module (rotation phenomenon). In consideration of this, by controlling the rotation speed of the first fan of the lower module to be greater than the rotation speed of the second fan, the intake amount of air sucked into the lower module can be controlled to be greater than the intake amount of the upper module. Accordingly, even if some of the air discharged from the lower module is sucked into the upper module, it is possible to prevent the amount of air discharged from the lower module from decreasing.

On the other hand, when the upper module is operated in a state in which the flow control device is in the first position that does not protrude upward, the rotation speed of the third fan of the flow control device is the rotation speed of the second fan of the upper module can be adjusted to match. If the second fan is driven but the third fan is not driven, the third fan may act as a resistor with respect to the air that has passed through the second fan. Accordingly, the third fan is driven at the same rotation speed as that of the second fan, thereby guiding the air passing through the second fan to be easily discharged upward.

1 is a perspective view showing an appearance of an air purifier according to an embodiment of the present invention.
2 is a perspective view illustrating an internal configuration of an air purifier according to an embodiment of the present invention.
FIG. 3 is a cross-sectional view taken along line III-III' of FIG. 2 .
4 is an exploded perspective view showing the configuration of an upper module according to an embodiment of the present invention.
5 is an exploded perspective view showing the configuration of a third air guide device and a second discharge guide device according to an embodiment of the present invention.
6 is an exploded perspective view illustrating a flow control device according to an embodiment of the present invention and a component to which the flow control device is coupled.
7 is a perspective view showing the configuration of a flow control device according to an embodiment of the present invention.
8 is a view showing a state in which the first guide mechanism acts for left and right rotation of the flow control device according to an embodiment of the present invention.
9 is an exploded perspective view showing the configuration of a flow control device according to an embodiment of the present invention.
10 is a view showing a state in which the second guide mechanism acts for vertical rotation of the flow control device according to an embodiment of the present invention.
11 is a view showing a state in which the flow control device according to the embodiment of the present invention is in the second position.
12 is a view showing the air flow through the air purifier when the flow control device according to the embodiment of the present invention is in the first position.
13 is a view showing the air flow through the air purifier when the flow control device according to the embodiment of the present invention is in the second position.
14 is a block diagram showing a control configuration of an air purifier according to an embodiment of the present invention.
15 is a flowchart illustrating a method for controlling an air purifier according to an embodiment of the present invention.
16 is a view showing air flow when only the lower module of the air purifier is driven according to an embodiment of the present invention.
17 is a view showing air flow when the upper module and the lower module of the air purifier according to an embodiment of the present invention are driven.
18 is a view showing an air flow state when the air cleaning module and the flow control device according to an embodiment of the present invention are driven.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function interferes with the understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the elements from other elements, and the essence, order, or order of the elements are not limited by the terms. When it is described that a component is "connected", "coupled" or "connected" to another component, the component may be directly connected or connected to the other component, but another component is between each component. It will be understood that may also be "connected", "coupled" or "connected".

1 is a perspective view showing an appearance of an air purifier according to an embodiment of the present invention.

Referring to FIG. 1 , in the air purifier 10 according to the embodiment of the present invention, there are blowers 100 and 200 for generating air flow and flow control for switching the discharge direction of the air flow generated by the blowers 100 and 200 . A device 300 is included. The blowers 100 and 200 include a first blower 100 for generating a first air flow and a second blower 200 for generating a second air flow.

The first blower 100 and the second blower 200 may be arranged in a vertical direction. For example, the second blower 200 may be disposed above the first blower 100 . In this case, the first air flow forms a flow for sucking indoor air existing on the lower side of the air purifier 10 , and the second air flow exists on the upper side of the air purifier 10 . Creates a flow that sucks in indoor air.

The first and second blowers 100 and 200 may be called "first air cleaning module 100" and second air cleaning module 200", respectively, in that they perform a function of purifying air in a clean space. In addition, the first blower 100 may be called a "lower air cleaning module" or "lower module" in that it is disposed under the air purifier 10, and the second blower ( 200) may be called an "upper air cleaning module" or "upper module" in that it is disposed on the upper portion of the air purifier 10 .

The air purifier 10 includes cases 101 and 201 that form an external appearance.

In detail, the cases 101 and 201 include a first case 101 that forms an exterior of the first blower 100 . The first case 101 may have a cylindrical shape. In addition, the upper portion of the first case 101 may be configured to have a smaller diameter than the lower portion. That is, the first case 101 may have a conical shape with an end cut off.

The first case 101 includes a first separation unit 101a to which two parts constituting the first case 101 are coupled or separated. A locking device such as a locking protrusion or a magnet member may be provided in the first separating part 101a. The two parts may be detachably coupled to the first separating part 101a by the locking device.

In the first case 101, a first suction unit 102 through which air is sucked is formed. The first suction unit 102 includes a through hole through which at least a portion of the first case 101 is penetrated. A plurality of the first suction units 102 are formed.

The plurality of first suction units 102 are uniformly formed along the outer circumferential surface of the first case 101 in a circumferential direction so that air can be sucked in any direction with respect to the first case 101 . That is, air may be sucked in a 360 degree direction based on the vertical center line passing through the inner center of the first case 101 .

As described above, since the first case 101 is configured in a cylindrical shape, and a plurality of the first suction units 102 are formed along the outer circumferential surface of the first case 101, an air intake amount can be increased. And, as in the case of a conventional air purifier, by avoiding the shape of a hexahedron having corners, there is an effect that the flow resistance to the sucked air can be reduced.

Air sucked in through the first suction unit 102 may flow in an approximately radial direction from the outer circumferential surface of the first case 101 . define the direction 1 , the vertical direction is called an axial direction, and the horizontal direction is called a radial direction. The axial direction may correspond to the central axis direction of the first fan 160 and the second fan 260 to be described later, that is, the motor axis direction of the fan. And, the radial direction may be understood as a direction perpendicular to the axial direction. Incidentally, the circumferential direction is understood as an imaginary circle direction formed when rotating with the axial direction as the center and the distance in the radial direction as the rotation radius.

The first blower 100 further includes a base 20 provided under the first case 101 and placed on the ground. The base 20 is positioned to be spaced downward from the lower end of the first case 101 . In addition, in the space between the first case 101 and the base 20, a base suction part 103 is formed. Air sucked through the base suction part 103 may flow upward through the suction port 112 of the suction grill 110 (refer to FIG. 2 ) provided on the upper side of the base 20 .

That is, the first blower 100 includes a plurality of suction units 102 and 103 . Air existing in the lower part of the indoor space may be easily introduced into the first blower 100 through the plurality of suction units 102 and 103 . Accordingly, the intake amount of air can be increased.

A first discharge part 105 is formed at an upper portion of the first blower 100 . The first discharge unit 105 may be formed on the first discharge grill 195 of the first discharge guide device 190 (refer to FIG. 2 ) provided in the first blower 100 . The first discharge guide device 190 forms the outer appearance of the upper end of the first blower 100 . Air discharged through the first discharge unit 105 may flow upward in the axial direction.

The cases 101 and 201 include a second case 201 that forms the exterior of the second blower 200 . The second case 201 may have a cylindrical shape. In addition, the upper portion of the second case 201 may be configured to have a smaller diameter than the lower portion. That is, the second case 201 may have a conical shape with an end cut off.

The second case 201 includes two parts that can be separated or coupled through a second separating part 201a provided with a locking device. The second case 201 may be configured to be openable like the first case 101 . For a detailed description, the description of the first case 101 is referred to.

The diameter of the lower end of the second case 201 may be smaller than the diameter of the upper end of the first case 101 . Accordingly, in view of the overall shape of the cases 101 and 201 , the lower cross-sectional areas of the cases 101 and 201 are formed to be larger than the upper cross-sectional areas, and thus the air purifier 10 can be stably supported on the ground.

The second case 201 is provided with a second suction unit 202 through which air is sucked. The second suction unit 202 includes a through hole through which at least a portion of the second case 201 is penetrated. A plurality of second suction units 202 are formed.

The plurality of second suction units 202 are uniformly formed along the outer circumferential surface of the second case 201 in the circumferential direction so that air can be sucked in any direction with respect to the second case 201 . That is, air may be sucked in a 360 degree direction based on the vertical center line passing through the inner center of the second case 201 .

As described above, since the second case 201 is configured in a cylindrical shape, and a plurality of the second suction units 202 are formed along the outer circumferential surface of the second case 201, the amount of air intake can be increased. And, as in the case of a conventional air purifier, by avoiding the shape of a hexahedron having corners, there is an effect that the flow resistance to the sucked air can be reduced. Air sucked in through the second suction part 202 may flow in a substantially radial direction from the outer peripheral surface of the second case 201 .

The air purifier 10 includes a partition device 400 provided between the first blower 100 and the second blower 200 . By the partition device 400 , the second blower 200 may be positioned to be spaced apart from the upper side of the first blower 100 .

The flow control device 300 may be installed above the second blower 200 . Based on the air flow, the air flow path of the second blower 200 may communicate with the air flow path of the flow control device 300 . The air that has passed through the second blower 200 may pass through the air passage of the flow control device 300 and be discharged to the outside through the second discharge unit 305 . The second discharge part 305 is formed at the upper end of the flow control device 300 .

The flow control device 300 may be movably provided. In detail, the flow control device 300 may be in a lying state (first position), as shown in FIG. 1 , or in an inclined standing state (second position) as shown in FIG. 13 . there is.

In addition, a display device 600 for displaying operation information of the air purifier 10 is provided at an upper portion of the flow control device 300 . The display device 600 may move together with the flow control device 300 .

2 is a perspective view showing the internal configuration of the air purifier according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view taken along line III-III' of FIG. 2 .

2 and 3 , the first blower 100 according to an embodiment of the present invention includes a base 20 and a suction grill 110 disposed above the base 20 .

The base 20 includes a base body 21 placed on the ground and a base protrusion 22 protruding upward from the base body 21 to place the suction grill 110 . The base protrusion 22 may be provided on both sides of the base 20 .

By the base protrusion 22, the base body 21 and the suction grill 110 are spaced apart from each other. Between the base 20 and the suction grill 110, a base suction part 103 forming an air suction space is formed.

The suction grill 110 includes a substantially ring-shaped grill body 111 and a rim that protrudes upward from the outer peripheral surface of the grill body 111 . By the configuration of the grill body 111 and the rim portion, the suction grill 110 may have a stepped configuration.

The suction grill 110 includes a suction part 112 formed in the edge portion. The suction part 112 is configured to protrude upward along the circumference of the edge part, and may be configured to extend in a circumferential direction. In addition, a plurality of suction holes 112a are formed inside the suction unit 112 . The plurality of suction holes 112a may communicate with the base suction unit 103 .

Air sucked through the plurality of suction holes 112a and the base suction unit 103 may pass through the first fulter member 120 . The first filter member 120 is provided in a cylindrical shape and may have a filter surface for filtering air. The air passing through the plurality of suction holes 112a may pass through the outer circumferential surface of the first cylindrical filter member 120 and be introduced therein.

The first blower 100 further includes a first filter frame 130 forming a mounting space for the first filter member 120 . In detail, in the first filter frame 130 , a first frame 131 forming a lower portion of the first filter frame 130 and a second frame 132 forming an upper portion of the first filter frame 130 . ) is included. The first and second frames 131 and 132 may have a substantially ring shape.

The first filter frame 130 further includes a first filter support part 135 extending upwardly from the first frame 131 toward the second frame 132 . A plurality of first filter support parts 135 may be provided, and the plurality of first filter support parts 135 may be arranged in a circumferential direction to be connected to edges of the first and second frames 131 and 132 . A mounting space of the first filter member 120 is defined by the first and second frames 131 and 132 and the plurality of first filter support parts 135 .

The first filter member 120 may be detachably mounted in the mounting space. The first filter member 120 has a cylindrical shape, and air may be introduced through the outer peripheral surface of the first filter member 120 . In the process of passing through the first filter member 120 , impurities such as fine dust in the air may be filtered out. Since the first filter member 120 has a cylindrical shape, air can be introduced from any direction with respect to the first filter member 120 . Accordingly, the filtering area of the air can be increased.

The first blower 100 further includes a first fan housing 150 installed at the outlet side of the first filter member 120 . A housing space 152 in which the first fan 160 is accommodated is formed in the first fan housing 150 . In addition, the first fan housing 150 may be supported by the first filter frame 130 .

The first blower 100 further includes an ionizer for removing or sterilizing odor particles in the air. The ionizer may be coupled to the first fan housing 150 and act on air flowing inside the first fan housing 150 .

The sensor device 137 and the ionizer may also be installed in a second blower 200 to be described later. As another example, the sensor device 137 and the ionizer may be installed in one of the first blower 100 and the second blower 200 .

The first fan 160 includes a centrifugal fan that introduces air in an axial direction and discharges air upward in a radial direction.

In detail, in the first fan 160 , a hub 161 to which a rotation shaft 165a of a first fan motor 165 , which is a centrifugal fan motor, is coupled, and a shroud 162 spaced apart from the hub 161 . ) and a plurality of blades 163 disposed between the hub 161 and the shroud 162 are included. The first fan motor 165 may be coupled to an upper side of the first fan 160 .

The first blower 100 further includes a first air guide device 170 coupled to the upper side of the first fan 160 to guide the flow of air passing through the first fan 160 . .

The first air guide device 170 includes an outer wall 171 having a cylindrical shape and an inner wall 172 positioned inside the outer wall 171 and having a cylindrical shape. The outer wall 171 is disposed to surround the inner wall 172 . A first air flow path through which air flows is formed between the inner circumferential surface of the outer wall 171 and the outer circumferential surface of the inner wall 172 .

The first air guide device 170 includes a guide rib 175 disposed in the first air passage. The guide rib 175 extends from the outer circumferential surface of the inner wall 172 to the inner circumferential surface of the outer wall 171 . A plurality of the guide ribs 175 may be disposed to be spaced apart from each other. The plurality of guide ribs 175 serve to upwardly guide the air introduced into the first air passage of the first air guide device 170 through the first fan 160 .

The first air guide device 170 further includes a motor accommodating part 173 extending downward from the inner wall 172 to accommodate the first fan motor 165 . The motor accommodating part 173 may be inserted inside the hub 161 .

The first fan motor 165 may be supported on the upper side of the motor accommodating part 173 . In addition, the rotating shaft of the first fan motor 165 extends downward from the first fan motor 165 , passes through the bottom surface of the motor accommodating part 173 , and is coupled to the shaft coupling part of the hub 161 . can be

In the first blower 100 , it is coupled to the upper side of the first air guide device 170 and guides the air passing through the first air guide device 170 to the first discharge guide device 190 . 2 The air guide device 180 is further included.

The second air guide device 180 includes a first guide wall 181 having a substantially cylindrical shape, and a second guide wall 181 positioned inside the first guide wall 181 and having a substantially cylindrical shape ( 182) is included. The first guide wall 181 may be disposed to surround the second guide wall 182 .

A second air flow path through which air flows is formed between the inner circumferential surface of the first guide wall 181 and the outer circumferential surface of the second guide wall 182 . The air flowing through the first air passage of the first air guide device 170 passes through the second air passage and flows upward. The second air flow path 185 may be referred to as a “discharge flow path”. In addition, the first discharge unit 105 is disposed above the second air flow path.

A first space in which at least a portion of the PCB device 500 is accommodated is formed inside the second guide wall 182 having a cylindrical shape.

In the first blower 100, the upper side of the second air guide device 180, that is, based on the air flow path, is disposed on the outlet side of the air flow passing through the second air guide device 180, A first discharge guide device 190 for guiding air discharge to the outside of the air purifier 10 is further included. A first discharge part 105 through which air is discharged is formed in the first discharge guide device 190 .

A partition device 400 is provided between the first blower 100 and the second blower 200 . The partition device 400 includes a partition plate 430 for separating or blocking the air flow generated from the first blower 100 and the air flow generated from the second blower 200 . . By the partition plate 430 , the first and second blowers 100 and 200 may be disposed to be vertically spaced apart from each other.

That is, a separation space in which the partition plate 430 is located is formed between the first and second blowers 100 and 200 . The first discharge guide device 190 of the first blower 100 is located at the lower end of the separation space, and the lever support device 560 of the second blower 200 is located at the upper end of the separation space. can be

The separation space may be divided into an upper space and a lower space by the partition plate 430 . The lower space is a space through which the air discharged from the first discharge unit 105 of the first discharge guide device 190 flows to the outside of the air purifier 10, and the upper space is It is understood as a holding space into which a hand can be put when moving the air purifier 10 . The air discharged from the first discharge unit 105 is guided by the partition plate 430 to flow to the outside of the air purifier 10, and can be prevented from flowing into the second blower 200 side. there is.

4 is an exploded perspective view showing the configuration of an upper module according to an embodiment of the present invention.

Referring to FIG. 4 , in the second blower 200 according to the embodiment of the present invention, a lever support device 560 , a lever device 242 , a support device 240 , a second filter member 220 , and a second The second filter frame 230 , the second fan housing 250 and the second fan 260 are included.

The second filter member 220 may have a cylindrical shape with an open top. Air may be introduced into the second filter member 220 through the outer circumferential surface of the second filter member 220 , and may be discharged through the open top of the second filter member 220 . The configuration of the second filter member 220 may also be used in the first filter member 120 .

The lever support device 560 supports the lever device 242 . In detail, the lever support device 560 includes a lever support body 561 having an annular shape. The lever support body 561 blocks the air discharged through the first discharge unit 105 of the first blower 100 from flowing into the second blower 200, and the "blocking" It can also be called "boo".

The lever support device 560 further includes a movement guide 565 protruding upward from the lever support body 561 . A plurality of the movement guide parts 565 may be disposed to be spaced apart from each other in the circumferential direction of the lever support body 561 .

The lever device 242 may be provided so that a user's operation is possible. For example, the lever device 242 may be provided to be rotatable in the circumferential direction. In detail, the lever device 242 includes a lever body 243 having a substantially ring shape and being rotatably provided. In addition, a plurality of cutouts 245 disposed at positions corresponding to the plurality of movement guide portions 565 are formed in the lever body 243 .

The lever device 142 is supported on the upper surface of the lever support body 561 . When the lever device 242 is supported by the lever support body 561 , the plurality of movement guides 565 may be disposed to be inserted into the plurality of cutouts 245 . In detail, the plurality of movement guides 565 may pass through the plurality of cutouts 245 and protrude upward of the plurality of cutouts 245 .

A support device 240 for supporting the second filter member 220 is provided above the lever device 242 . In detail, the lever device 242 supports the lower surface of the support device 240 . The support device 240 may include a support protrusion (not shown) in contact with the movement guide part 565 . The support protrusion protrudes downward from the lower surface of the support device 240 , and may be provided at a position corresponding to the movement guide part 565 . In addition, the shape of the support protrusion corresponds to the shape of the movement guide 565 and includes an inclined surface that is formed to gradually protrude in the circumferential direction. In addition, the direction in which the movement guide part 565 is formed to gradually protrude and the direction in which the support protrusion is formed to gradually protrude may be opposite to each other.

The lever device 242 and the support device 240 may be rotated together. During this rotation, the movement guide 565 and the support protrusion may interfere. In detail, when the lower portion of the support protrusion and the upper portion of the movement guide 565 contact each other, the lever device 242 and the support device 240 are lifted upward. And, the first filter member 220 supported by the support device 240 is in a state coupled to the first blower 200 while moving upward.

On the other hand, when the upper part of the support protrusion and the lower part of the movement guide part 565 come into contact with each other or the interference between the support protrusion part and the movement guide part 565 is released, the lever device 242 and the support device 240 . is coming down In addition, the first filter member 220 supported by the support device 240 is in a detachable state (released state) from the first blower 100 .

The second blower 200 further includes a second filter frame 230 forming a mounting space for the second filter member 220 . In detail, in the second filter frame 230 , a first frame 231 forming a lower portion of the first filter frame 230 and a second frame forming an upper portion of the second filter frame 230 ( 232 ) and a second filter support 235 extending upward from the first frame 231 toward the second frame 232 . The description of the first and second frames 231,232 and the second filter support 235 is the same as the description of the first and second frames 131 and 132 and the first filter support 135 of the first filter frame 130 . wish to

A mounting space for the second filter member 220 is defined by the first and second frames 231,232 and the plurality of second filter support parts 235 . In addition, the first support part cover 236 may be coupled to the outside of the second filter support part 235 .

A sensor device 237 may be installed in the second filter frame 230 . The sensor device 237 may include a dust sensor 237a for detecting an amount of dust in the air and a gas sensor 237b for detecting an amount of gas in the air. The dust sensor 237a and the gas sensor 237b may be disposed to be supported by the second frame 232 of the second filter frame 230 . The sensor device 237 further includes a sensor cover 237c covering the dust sensor 237a and the gas sensor 237b.

In this embodiment, it has been described that the sensor device 237 is installed in the second blower 200 , but otherwise, the sensor device 237 may be installed in the first blower 100 . . That is, the sensor device 237 may be installed in the first blower 100 or the second blower 200 .

The second filter member 220 may be detachably mounted in the mounting space. The first filter member 220 has a cylindrical shape, and air may be introduced through the outer peripheral surface of the second filter member 220 . In the process of passing through the second filter member 220 , impurities such as fine dust in the air may be filtered out.

The second blower 200 further includes a second fan housing 250 installed at the outlet side of the second filter member 220 . In the second fan housing 250 , a housing space 252 in which the second fan 260 is accommodated is formed. Since the configuration of the second fan housing 250 and the second fan 260 is the same as that of the first fan housing 150 and the first fan 160, the configuration of the second fan housing 250 and the second fan 260 is the same. The description of the second fan 260 refers to the description of the first fan housing 150 and the first fan 160 .

The second blower 200 further includes an ionizer 258 for removing or sterilizing odor particles in the air. The ionizer 258 is coupled to the first fan housing 250 , and may act on air flowing inside the second fan housing 250 . The ionizer 258 may have the same configuration as the ionizer of the first blower 100 .

5 is an exploded perspective view showing the configuration of a third air guide device and a second discharge guide device according to an embodiment of the present invention, and FIG. 6 is a flow control device according to an embodiment of the present invention and the flow control device are coupled It is an exploded perspective view showing the configuration of the parts, FIG. 7 is a perspective view showing the configuration of the flow control device according to an embodiment of the present invention, and FIG. It is a drawing showing how the guide mechanism works.

5 to 8 , in the second blower 220 according to the embodiment of the present invention, the flow of air coupled to the upper side of the second fan 260 and passed through the second fan 260 . A third air guide device 270 for guiding the is further included.

The third air guide device 270 has an outer wall 271 that forms an outer circumferential surface of the third air guide device 270 and is located inside the outer wall 271 of the third air guide device 270 . An inner wall 272 defining an inner circumferential surface is included. A first air flow path 272a through which air flows is formed between the inner circumferential surface of the outer wall 271 and the outer circumferential surface of the inner wall 272 .

In addition, the third air guide device 270 includes a guide rib 275 disposed in the first air passage 272a. The guide rib 275 extends from an outer circumferential surface of the inner wall 272 to an inner circumferential surface of the outer wall 271 .

The third air guide device 270 further includes a motor accommodating part 273 extending downward from the inner wall 272 to accommodate the second fan motor 265 . The motor accommodating part 273 may have the shape of a bowl whose diameter decreases toward the bottom.

The second fan motor 265 is coupled to the upper side of the second fan 260 to provide a driving force to the second fan 260 . A motor coupling part 266 is provided on one side of the second fan motor 265 , and the motor coupling part 266 connects the second fan motor 265 to the third air guide device 270 . guide it to be fixed.

The third air guide device 270 includes guide devices 276 and 277 for guiding the movement of the flow control device 300 . The guide devices 276 and 277 include a first rack 276 and a shaft guide groove 277 provided in the motor accommodating part 273 .

The first rack 276 is understood as a configuration for guiding the left-right rotation of the flow control device 300 in association with the first gear 360 of the flow control device 300 . The first rack 276 is provided on the inner circumferential surface of the motor accommodating part 273, and may extend in the circumferential direction according to a set curvature. In addition, the length of the first rack 276 may be formed to a length set based on a distance interlocked with the first gear 360 .

The flow control device 300 may be rotated in the left and right directions. Here, "rotation in the left and right direction" may mean rotation in a clockwise or counterclockwise direction based on the vertical direction. In this process, the first gear 360 may rotate with a predetermined rotation radius around the rotation shaft 354 of the flow control device 300 .

The shaft guide groove 277 is a groove for guiding the rotation of the first gear 360 and is understood as a configuration that extends roundly with a predetermined curvature. For example, the shaft guide groove 277 may be formed to be rounded in the circumferential direction. That is, the shaft guide groove 277 may have a circular arc shape.

A first gear shaft 362 of the first gear 360 may be inserted into the shaft guide groove 277 . While the first gear 360 rotates, the first gear shaft 362 may move along the shaft guide groove 277 .

The second blower 200 has a second discharge guide device 280 that is installed above the third air guide device 270 and guides the flow of air passing through the third air guide device 270 . ) is provided.

The second discharge guide device 280 may have a substantially annular shape. In detail, in the second discharge guide device 280, the outer circumferential surface of the second discharge guide device 280 is formed and the discharge outer wall 281 having a cylindrical shape and the discharge outer wall 281 are located inside the The discharge inner wall 282 forming the inner circumferential surface of the second discharge guide device 280 and having a cylindrical shape is included.

The discharge outer wall 281 is disposed to surround the discharge inner wall 282 . Between the inner circumferential surface of the discharge outer wall 281 and the outer circumferential surface of the discharge inner wall 282, a second air flow path 282a through which air flows through the third air guide device 270 through which air flows. , that is, a discharge passage is formed. The discharge flow path may be located above the first air flow path 272a provided with the guide rib 275 .

The second discharge guide device 280 further includes a second discharge grill 288 disposed in the discharge passage 282a. The second discharge grill 288 extends from an outer circumferential surface of the discharge inner wall 282 to an inner circumferential surface of the discharge outer wall 281 . The second discharge grill 288 may prevent the user from inserting a finger into the lower side of the discharge passage 282a.

The second discharge guide device 280 further includes a rotation guide plate 283 coupled to the discharge inner wall 282 . The rotation guide plate 283 may extend from an inner circumferential surface of the discharge inner wall 282 toward an inner center of the second discharge guide device 280 .

The rotation guide plate 283 includes a shaft insertion portion 284 that provides a center of rotation in the left and right directions of the flow control device 300 . The rotation shaft 354 may be inserted into the shaft insertion part 284 . The shaft insertion part 284 may be located at an inner center of the second discharge guide device 280 . The rotation guide plate 283 may be understood as a support plate for supporting the shaft insertion part 284 .

The rotation guide plate 283 further includes a bearing groove 285 . A first bearing 353 provided in the flow control device 300 may be inserted into the bearing groove 285 . The bearing groove 285 is understood as a configuration extending roundly with a curvature set as a groove for guiding the movement of the first bearing 353 . For example, the bearing groove 285 may be formed to be rounded in a circumferential direction. That is, the bearing groove 285 may have a circular arc shape.

In the process of rotating the flow control device 300 in the left and right directions, the first bearing 353 is inserted into the bearing groove 285 to move, and accordingly, generated during the rotation of the flow control device 300 . friction can be reduced.

The flow control device 300 includes a third fan housing 310 in which the third fan 330 is accommodated. The third fan housing 310 has a substantially annular shape. For convenience of description, the first fan 160 and the second fan 260 may be referred to as a “blowing fan” and the third fan 330 may be referred to as a “circulation fan”.

On the upper side of the third fan housing 310 , a discharge grill 315 forming a second discharge unit 305 through which air passing through the third fan 330 is discharged is provided. Since the air purifier 10 is provided with the second discharge unit 305 together with the first discharge unit 105 of the first blower 100, the discharge air volume is improved and air is discharged in various directions. effect appears. In addition, the display device 600 may be provided in a central portion of the discharge grill 315 .

The third fan 330 may include an axial fan. In detail, the third fan 330 may be operated to discharge the air introduced in the axial direction in the axial direction. That is, the air flowing upward toward the third fan 330 through the second fan 260 , the third air guide device 270 , and the second discharge guide device 280 is the third It may be discharged from the fan 330 and discharged to the outside through the second discharge unit 305 positioned above the third fan 330 .

In the third fan 330 , a hub 331 having a shaft coupling portion to which a rotation shaft of a third fan motor 335 , which is an axial fan motor, is coupled, and a plurality of blades 333 circumferentially coupled to the hub 331 . ) is included. The third fan motor 335 may be coupled to a lower side of the third fan 330 .

The first fan motor 165 and the second fan motor 265 may be arranged in a line with respect to the longitudinal direction of the air purifier 10 . In addition, the second fan motor 265 and the third fan motor 335 may be arranged in a line with respect to the longitudinal direction of the air purifier 10 . That is, the fan motors 165 , 265 , and 335 may be positioned on the same longitudinal axis. In other words, the fans 160 , 260 , and 330 may be positioned on the same longitudinal axis.

In the flow control device 300 , a flow guide part coupled to the lower side of the third fan housing 310 to guide the air passing through the second discharge guide device 280 to the third fan housing 310 ( 320) is further included. The flow guide part 320 includes an inlet grill 325 for guiding the inflow of air into the third fan housing 310 . The inlet grill 325 may have a downwardly concave shape.

In addition, the shape of the second discharge grill 288 of the second discharge guide device 280 is formed to be concave downward corresponding to the shape of the inlet grill 325 . The inlet grill 325 may be seated on an upper side of the second outlet grill 288 . With this configuration, the inlet grill 325 can be stably supported by the second outlet grill 288 .

The flow control device 300 includes a rotation guide device 350 installed below the flow guide part 320 to guide the left and right rotation and the vertical rotation of the flow control device 300 . more included. The rotation in the left and right direction may mean rotation in a clockwise or counterclockwise direction based on the axial direction. The horizontal rotation may be referred to as a “first direction rotation” and the vertical rotation may be referred to as a “second direction rotation”.

The rotation guide device 350 includes a first guide mechanism for guiding the rotation of the flow control device 300 in the first direction and a second guide mechanism for guiding the rotation of the flow control device 300 in the second direction. is included

In detail, the first guide mechanism includes a first gear motor 363 that generates a driving force and a first gear 360 that is coupled to the first gear motor 363 to be rotated. For example, the first gear motor 363 may include a step motor that facilitates control of the rotation angle. In addition, the first gear motor 363 may include a motor capable of bidirectional rotation.

The first guide mechanism includes a first gear shaft 362 extending downward from the first gear 360 , that is, toward the third air guide device 270 or the second discharge guide device 280 . more included.

The first gear 360 is gear-coupled to the first rack 276 of the third air guide device 270 . A plurality of gear teeth are formed in the first gear 360 and the first rack 276 . And, when the first gear motor 363 is driven, the first gear 360 rotates and interlocks with the first rack 276 . At this time, since the third air guide device 270 has a fixed configuration, the first gear 360 may be moved along the first rack 276 .

The shaft guide groove 277 of the third air guide device 270 may guide the movement of the first gear 360 . In detail, the first gear shaft 362 may be inserted into the shaft guide groove 277 . In addition, the first gear shaft 362 may be moved in the circumferential direction along the shaft guide groove 277 while the first gear 360 rotates.

The first guide mechanism further includes a rotation shaft 354 constituting a rotation center of the flow control device 300 . The first gear 360 and the first gear shaft 362 may be rotated with a rotation radius set around the rotation shaft 354 . At this time, the set turning radius is called a "first turning radius".

The rotation shaft 354 is provided on the bottom surface of the rotation guide device 350 and is inserted into the shaft insertion part 284 of the second discharge guide device 280, and can be rotated within the shaft insertion part 284. there is. That is, when the first gear 360 rotates, the first gear shaft 362 and the first gear 360 rotate in the circumferential direction about the rotation shaft 354 . In addition, the rotation shaft 354 rotates within the shaft insertion part 284 . Accordingly, the flow control device 300 may be rotated in the first direction, ie, clockwise or counterclockwise, with the longitudinal direction as the axial direction.

The first guide mechanism further includes bearings 353 and 355 for facilitating rotation of the flow control device 300 in the first direction. The bearings 353 and 355 may reduce frictional force generated during the rotation of the flow control device 300 .

The bearings 353 and 355 include a first bearing 353 provided on a bottom surface of the rotation guide device 350 . For example, the first bearing 353 may include a ball bearing.

The rotation guide plate 283 includes a bearing groove 285 into which the first bearing 353 is inserted. While the flow control device 300 rotates in the first direction, the first bearing 353 may be inserted into the bearing groove 285 to move.

In this case, the first bearing 353 may be rotated with a rotation radius set around the rotation shaft 354 . At this time, the set turning radius is referred to as a "second turning radius". The second turning radius may be smaller than the first turning radius.

The bearings 353 and 355 further include the second bearing 355 . The second bearing 355 may be rotatably installed on the edge of the rotation guide device 350 . The second bearing 355 may be provided to be in contact with the discharge inner wall 282 of the second discharge guide device 280 , that is, the inner circumferential surface of the discharge inner wall 282 is the second bearing 355 . ) can form a contact surface. As the second bearing 355 rotates along the inner circumferential surface of the discharge inner wall 282 about the rotation shaft 354 , rotation of the flow control device 300 in the first direction can be easily achieved.

Referring to FIG. 8 , the rotation of the flow control device 300 in the first direction will be briefly described. When the first gear motor 363 operates, the first gear 360 may rotate. When viewed from above, the first gearmotor 363 rotates in a clockwise or counterclockwise direction, and correspondingly, the first gear 360 rotates in the clockwise or counterclockwise direction.

For example, when the first gear motor 363 rotates clockwise, the first gear 360 and the first gear shaft 362 may move counterclockwise along the shaft guide groove 277 . . On the other hand, when the first gear motor 363 rotates counterclockwise, the first gear 360 and the first gear shaft 362 may move clockwise along the shaft guide groove 277 . .

According to the movement of the first gear 360 in the clockwise or counterclockwise direction, the flow control device 300 may rotate in the same direction as the movement direction of the first gear 360 . In this process, the first bearing 353 may move along the bearing groove 285 , and the second bearing 355 may move along the inner circumferential surface of the discharge inner wall 282 . By this action, the flow control device 300 can be stably rotated along a set path in the left and right directions.

9 is an exploded perspective view showing the configuration of a flow control device according to an embodiment of the present invention, and FIG. 10 is an exploded perspective view showing the action of the second guide mechanism for vertical rotation of the flow control device according to an embodiment of the present invention It is a drawing.

7 and 9 , the flow control device 300 according to the embodiment of the present invention includes a second guide mechanism for guiding the vertical rotation of the flow control device 300 . In detail, the second guide mechanism includes a fixed guide member 352 fixed to the guide body 351 . The central shaft 354 may be provided on a lower surface of the fixing guide member 352 .

The fixed guide member 352 includes a first guide surface 352a that supports the lower side of the rotation guide member 370 and guides the rotation of the rotation guide member 370 in the second direction. The first guide surface 352a forms at least a portion of an upper surface of the fixed guide member 352 , and may extend upward in a round manner in response to a rotation path of the rotation guide member 370 .

The fixed guide member 352 includes a first guide bearing 359 that is provided to be in contact with the rotation guide member 370 and can reduce frictional force generated during the rotational movement of the rotation guide member 370 . more included. The first guide bearing 359 may be positioned on the side of the first guide surface 352a.

The fixed guide member 352 further includes a second gear insertion part 352b into which a second gear 365 can be inserted for rotation of the rotation guide member 370 . The second gear insertion part 352b is formed on one side of the first guide surface 352a. For example, the second gear insertion part 352b may be formed by cutting at least a portion of the first guide surface 352a.

The second gear 365 is positioned below the first guide surface 352a, and at least a portion of the second gear 365 penetrates the second gear insertion part 352b to insert the second gear. It may be configured to protrude upward of the portion 352b.

The second guide mechanism further includes a second gear motor 367 coupled to the second gear 365 to provide a driving force. For example, the second gear motor 367 may include a step motor. In addition, the second gear motor 367 may include a motor capable of bidirectional rotation.

The second guide mechanism further includes a second gear shaft 366 extending from the second gear motor 367 to the second gear 365 . The second gear shaft 366 may protrude laterally of the second gear motor 367 . When the second gear motor 367 is driven, the second gear shaft 366 and the second gear 365 may rotate together.

The second guide mechanism further includes a rotation guide member 370 disposed above the fixed guide member 352 and rotatably provided in the vertical direction. The rotation guide member 370 may be coupled to a lower side of the flow guide part 320 .

In detail, the rotation guide member 370 includes a body portion 371 supported by the fixed guide member 352 . In addition, the body portion 371 includes a second guide surface 372 that moves along the first guide surface 352a. The second guide surface 372 may be formed to be rounded downward corresponding to the curvature of the first guide surface 352a.

The rotation guide member 370 has a second guide bearing 375 which is provided to be in contact with the fixed guide member 352 to reduce frictional force generated during the rotational movement of the rotation guide member 370 . more included. The second guide bearing 375 is positioned on the side of the second guide surface 372 , and may move along the first guide surface 352a while the rotation guide member 370 rotates.

The rotation guide member 370 further includes a second rack 374 interlocking with the second gear 365 . A plurality of gear teeth are formed in the second gear 365 and the second rack 374, and through the plurality of gear teeth, the second gear 365 and the second rack 374 are gear-coupled to each other. can

When the second gear motor 367 is driven, by interlocking the second gear 365 and the second rack 374, the rotation guide member 370 can perform a vertical rotation movement. there is. Accordingly, the flow control device 300 may perform rotation in the second direction according to the movement of the rotation guide member 370 .

Referring to FIG. 10 , the second direction rotation of the flow control device 300 will be briefly described. When the second gear motor 367 operates, the second gear 365 may rotate. The second gear motor 367 rotates in a clockwise or counterclockwise direction based on the radial direction, and the second gear 365 may rotate in the clockwise or counterclockwise direction in response thereto.

For example, when the second gearmotor 367 rotates clockwise, the second gear 365 rotates in the clockwise direction and the second rack 374 interlocks with the second gear 365 to rotate It can be rotated clockwise. As the second rack 374 rotates, the rotation guide member 370 and the flow guide part 320 may rotate together. As a result, the fan housing 310 may rotate counterclockwise.

On the other hand, when the second gearmotor 367 rotates counterclockwise, the second gear 365 rotates counterclockwise and the second rack 374 is interlocked with the second gear 365 . to rotate clockwise. As the second rack 374 rotates, the rotation guide member 370 and the flow guide part 320 may rotate together. As a result, the fan housing 310 may rotate in a clockwise direction. By this action, the flow control device 300 can be stably rotated along a set path in the vertical direction.

11 is a view showing a state in which the flow control device according to the embodiment of the present invention is in the second position, and FIG. 12 is a view showing that the flow control device according to the embodiment of the present invention is in the first position, through the air purifier. It is a view showing the air flow, and FIG. 13 is a view showing the air flow through the air purifier when the flow control device according to the embodiment of the present invention is in the second position.

11 shows a state in which the flow control device 300 protrudes upward of the second discharge guide device 280, that is, the rotation guide member 370 is rotated upward so that the fan housing 310 is erected upward. Shows the state (second position).

The flow control device 300 may be rotatably up and down in the direction of “B” shown in FIG. 11 , and may be in the first position (see FIG. 1 ) or the second position. When the flow control device 300 is in the first position, the inlet grill 325 is seated on the upper surface of the second outlet grill 288 . On the other hand, when the flow control device 300 is in the second position, the inlet grill 325 may be upwardly spaced apart from the upper surface of the second outlet grill 288 .

The third fan 330 may selectively operate depending on whether the flow regulator 300 is in the first position or the second position.

In detail, referring to FIG. 12 , in a state in which the flow control device 300 is in the first position, the first and second fans 160 and 260 may rotate to generate an air flow. By the operation of the first fan 160 , air intake and discharge (first flow) from the lower portion of the air purifier 10 may be generated. And, by the operation of the second fan 260 , air intake and discharge (second flow) from the upper portion of the air purifier 10 may be generated. The first flow and the second flow may be separated by the partition device 400 .

In addition, the third fan 330 may selectively operate. When the third fan 330 operates, the second flow may be generated more strongly. That is, by the second fan 260 and the third fan 330 , a strong discharge air flow from the upper portion of the air purifier 10 is generated and may be discharged through the second discharge unit 305 . Of course, the third fan 330 may not operate.

Meanwhile, in a state in which the flow control device 300 is in the second position, the first and second fans 160 and 260 may rotate to generate the first and second flows. And, the third fan 330 may operate. The second position is understood to be a position inclined upward by a set angle with respect to the first position of the flow control device 300 . For example, the set angle may be about 60 degrees.

In detail, referring to FIG. 13 , by the operation of the third fan 330 , at least a portion of the air discharged through the second discharge guide device 280 is transferred to the inside of the third fan housing 310 . It may be introduced into the air, and may be discharged from the second discharge unit 305 through the third fan 330 . By this action, the purified air can reach a location far away from the air purifier 10 .

In addition, the flow control device 300 may be rotated in the left and right directions with respect to the axial direction in the second position. FIG. 11 shows a state in which the flow control device 300 is positioned to face one direction (left direction based on FIG. 11 ) in the second position. Here, the one direction may be a direction toward the left 45 degrees centering on the front of the air purifier (10).

The flow control device 300 may be positioned to face the other direction in the second position. Here, the other direction may be a direction toward the right 45 degrees centering on the front of the air purifier (10). That is, the rotation angle of the flow control device 300 may form about 90 degrees.

In this way, since the flow control device 300 can be rotated in the left and right directions based on the axial direction, there is an effect that the discharge air flow can be sent to a long distance in various directions centering on the air purifier 10 .

14 is a block diagram showing a control configuration of an air purifier according to an embodiment of the present invention.

Referring to FIG. 14 , the air purifier 10 according to the embodiment of the present invention includes a sensor device 237 . The sensor device 237 may include a dust sensor 237a. The dust sensor 237a may detect an amount of impurities or dust that is less than a set size in the air sucked into the upper module 200 . For example, the dust sensor 237a may be configured to detect an amount of ultrafine dust of 2.5 μm or less. Accordingly, the dust sensor 237a may be referred to as a “PM2.5 dust sensor”.

The sensor device 237 may further include a gas sensor 237b. The gas sensor 237b may detect an amount of a harmful gas, for example, a combustible gas, a reducing gas, and an organic solvent gas included in the air sucked into the upper module 200 .

air quality level One 2 3 4 5 6 7 Pollution degree (cleanliness) good commonly bad very bad display color green yellow Orange Red

Based on the information sensed by the dust sensor 237a and the gas sensor 237b, an air condition, that is, an air quality level may be determined. In detail, the air quality level may be determined by combining the values output from the dust sensor 237a and the gas sensor 237b. For example, the air quality level may be classified from level 1 to level 7, and the higher the level, the worse the air condition may be recognized.

And, in the section where the air quality level is 1 to 2, the air pollution degree (cleanliness) is “good”, and in the section where the air quality level is 3 to 4, the air pollution degree (cleanliness) is “normal”, and the air quality In the section where the level is 5 to 6, the air pollution degree (cleanliness) may be recognized as “poor”, and in the section where the air quality level is 7, the air pollution degree (cleanliness) may be recognized as “very bad”.

The display device 600 may display level information regarding the degree of air pollution. For example, the information on the air pollution level may be displayed in color. In detail, when it is recognized that the air pollution level is "good", the display device 600 outputs "green".

On the other hand, when it is recognized that the air pollution level is "normal", the display device 600 outputs "yellow", and when it is recognized that the air pollution level is "normal", the display device 600 displays " Orange" can be printed. And, when it is recognized that the air pollution level is "very bad", the display device 600 outputs "red". As described above, since the information on the air pollution level is displayed in distinguishable colors, there is an advantage in that the user can intuitively recognize the information on the air quality.

The air purifier 10 further includes an input unit 710 through which a user can input a predetermined command. The input unit 710 includes a power input unit 711 capable of turning on or off the power of the air purifier 10 .

The input unit 710 further includes an operation mode input unit 713 capable of inputting a command regarding an operation mode of the air purifier 10 while the power of the air purifier 10 is turned on.

The operation mode of the air purifier 10 may include a manual operation mode and an automatic operation mode. The user may select any one of the manual operation mode and the automatic operation mode through the operation mode input unit 713 . For example, the operation mode input unit 713 may include a separate input unit for selecting each operation mode.

When the manual operation mode is selected through the operation mode input unit 713 , the user may input the number of modules (devices) to be operated or the wind strength (air volume). In detail, the input unit 710 further includes a clean mode input unit 715 for determining the number of modules to be operated. The module may include three modules, namely, the first air cleaning module 100 , the second air cleaning module 200 , and the flow control device 300 . The three modules can be operated selectively or independently.

The clean mode input unit 715 is configured to determine the number of modules to be operated among the three modules. In detail, the clean mode input unit 715 may include "single clean input unit", "dual clean input unit" and "circulation clean input unit". The single clean input unit is an input unit that can be input to operate the first air cleaning module 100 among the three modules, and the dual clean input unit operates the first and second air cleaning modules 100 and 200 It is understood as an input unit that can be input for In addition, the circulation cleaning input unit is understood as an input unit that can be input to operate the first and second air cleaning modules 100 and 200 and the flow control device 300 .

When the single clean input unit is input, the air purifier 10 operates in "single mode" in which the independent operation of the lower module 100 is performed, and when the dual clean input unit is input, the air purifier 10 operates the upper and lower modules ( 100, 200) may be operated in a "dual mode" in which the combined operation is performed. And, when the circulation cleaning input unit is input, the air purifier 10 may be operated in a "circulation mode" in which the combination operation of the upper and lower modules 100 and 200 and the flow control device 300 is performed. Here, the operation of the flow control device 300 in the “circulation mode” means a case in which the flow control device 300 is operated in a state in which the flow control device 300 protrudes obliquely to the upper side of the upper module 200 .

The input unit 710 further includes an air volume input unit 717 capable of determining the strength of the air discharged from the module to be operated, that is, the air volume. After determining the module to be operated through the clean mode input unit 715 , the user may determine the air volume discharged from the module through the air volume input unit 717 . As an example, the wind volume may be divided into “weak wind”, “medium wind” and “strong wind”. Of course, the number of rotations of the first fan 160 , the second fan 260 , or the third fan 330 may be determined according to the determined air volume.

On the other hand, when the automatic operation mode is selected through the operation mode input unit 713 , the air purifier 10 determines the number of modules to be operated and the wind strength based on the air pollution level recognized by the sensor device 237 . (Air volume) can be determined.

For example, when the air pollution level is "good" or "normal", it is determined that the first air cleaning module 100 is operated among the modules, and when the air pollution level is "bad", It may be determined that the first and second air cleaning modules 100 and 200 among the modules are operated.

The pollution level of the “normal state”, that is, the air quality level 4 is understood as the first reference pollution level capable of operating only the first air cleaning module 100 . And, the pollution level of the “bad state”, that is, the air quality level 6 is understood as the second reference pollution level capable of operating the first and second air cleaning modules 100 and 200 . That is, when the pollution level is equal to or higher than the first standard pollution degree and less than or equal to the second standard pollution degree, the first and second air cleaning modules 100 and 200 may be operated.

At a pollution level greater than or equal to the second reference pollution degree, all of the three modules may be operated. In detail, when the air pollution level is "very bad", it may be determined that all of the three modules, that is, the first and second air cleaning modules 100 and 200 and the flow control device 300 are operated. When it is determined as the module in which the flow control device 300 is operated, the flow control device 300 may be operated by moving to the second position (see FIG. 13 ).

When a module to be operated is determined based on the air pollution level information, the amount of air discharged from the operation-determined module may be preset. For example, the preset wind amount may be “weak wind”.

Meanwhile, through the automatic operation mode, when the air volume input unit 717 is input while a predetermined module is operated with “weak wind”, the air volume discharged from the operated module may be adjusted according to preset information. The reason that the user inputs the air volume input unit 717 is that the user may be recognized as wanting a stronger air volume.

For example, when the air pollution level is "good", the first air cleaning module 100 can maintain a good air cleaning level even when the first air cleaning module 100 is operated in "weak wind". ) does not change the airflow. In addition, a guide message may be output to the user through the display device 600 . For example, the guide message may include "The air condition is good, and the clean condition can be maintained only by the current operation". Nevertheless, when the user requests a strong air volume, the display device 600 may guide the transition to the “manual operation mode”.

On the other hand, when the air pollution level is "normal", the air volume of the first air cleaning module 100 may be adjusted to "medium wind". In addition, a message indicating that the air volume of the first air cleaning module 100 has been adjusted from “weak wind” to “medium wind” may be output to the user.

On the other hand, when the air pollution level is "bad", the air volume of the first and second air cleaning modules 100 and 200 may be adjusted to "medium air", respectively. In addition, a message indicating that the air volume of the first and second air cleaning modules 100 and 200 has been adjusted from “weak wind” to “medium wind” may be output to the user.

On the other hand, when the air pollution level is "very bad", the air volumes of the first and second air cleaning modules 100 and 200 and the flow control device 300 may be adjusted to "strong wind", respectively. In addition, a message indicating that the air volume of the first and second air cleaning modules 100 and 200 and the flow control device 300 has been adjusted from “weak wind” to “strong wind” may be output to the user.

The air purifier 10 further includes a memory unit 720 for storing information preset for operation of the air purifier 10 . The memory unit 720 may store the information shown in [Table 1]. That is, the value sensed by the sensor device 237 , mapping information about an air quality level, mapping information about a pollution level, and mapping information about a display color may be stored. In addition, when the automatic operation mode is selected in the memory unit 720 , information about the number of modules to be operated and an air volume may be stored.

The air purifier 10 includes a first fan motor 165 based on information detected by the sensor device 237 , information input through the input unit 710 or information stored in the memory unit 720 . , the second fan motor 265 , the third fan motor 335 , the first gear motor 363 , the second gear motor 367 , or the control unit 700 for controlling the driving of the display device 600 is further Included. The control unit 700 may determine whether to operate the three modules according to the operation mode of the air purifier 10 , and may determine the air volume of the three modules according to input or pre-stored information.

15 is a flowchart illustrating a method for controlling an air purifier according to an embodiment of the present invention. A method of controlling the air purifier 10 according to an embodiment of the present invention will be described with reference to FIG. 15 .

The air purifier 10 is turned on and an operation mode may be selected (S11). If the selected operation mode is the manual operation mode, the user may input a module to be operated among the three modules through the clean mode input unit 715 , and may determine the discharge air volume of the module determined to be operated through the air volume input unit 717 . That is, the user selects any one of the single mode, the dual mode and the circulation mode of the air purifier 10 . The air purifier 10 can be operated (S13 and S14).

In addition, the number of rotations of the fans 160 , 260 , and 330 provided in each module may be determined in response to the determined discharge air volume. That is, the controller 700 may control the rotation speed of the fans 160 , 260 , and 330 based on preset rotation speed information of the fan motors 165 , 265 , and 335 , and drive each module.

In detail, when the single mode of the air purifier 10 is selected (see FIG. 16 ), the controller 700 may control the rotation speed of the first fan motor 165 . For example, when the air volume selected by the user is "weak wind", the number of rotations of the first fan motor 165 is N0, and when it is "medium wind", the number of rotations of the first fan motor 165 is N0'. , in the case of "strong wind", the number of rotations of the first fan motor 165 may be determined as N0''. Of course, N0''>N0'>N0 may hold. In addition, the second fan motor 265 and the third fan motor 335 may be turned off.

When the dual mode of the air purifier 10 is selected (refer to FIG. 17 ), the controller 700 may control the rotation speed of the first fan motor 165 and the second fan motor 265 . For example, in the case of "weak wind", the rotation speed of the second fan motor 265 may be N1, and the rotation speed of the first fan motor 165 may be N1'.

The N1' may be a value greater than the N1. At least a portion of the air discharged from the lower module 100 may be sucked back into the second suction unit 202 of the upper module 200 (rotation phenomenon). In consideration of this, by controlling the rotation speed of the first fan 160 of the lower module 100 to be greater than the rotation speed of the second fan 260, the amount of air sucked into the lower module 100 is increased. It can be controlled to be greater than the suction amount of the upper module 200 . Therefore, even if some of the air discharged from the lower module 100 is sucked into the upper module 200 , it is possible to prevent the amount of air discharged from the lower module 100 from being reduced.

Meanwhile, the third fan motor 335 may also be driven at a set rotation speed. If the upper module 200 is operated but the third fan 330 is not driven, the third fan 330 may act as a resistor with respect to the air passing through the second fan 260 . can Accordingly, the rotation speed N1 ″ of the third fan 330 may be adjusted to correspond to the rotation speed N1 of the second fan 260 . For example, the rotation speed of the third fan 330 may be controlled to be the same as the rotation speed of the second fan 260 . By such control, the air that has passed through the second fan 260 may be easily discharged upward through the third fan 330 .

Similarly, even if the selected air volume is “medium wind” or “strong wind”, the rotation speed of the first fan motor 165 is greater than the rotation speed of the second fan motor 265 , and the rotation speed of the third fan motor 335 is greater than that of the third fan motor 335 . The number of rotations may be controlled by the number of rotations corresponding to the number of rotations of the second fan motor 265 .

When the circulation mode of the air purifier 10 is selected (see FIG. 18 ), the control unit 700 rotates the first fan motor 165 , the second fan motor 265 , and the third fan motor 335 . number can be controlled. For example, in the case of "weak wind", the rotation speed of the second fan motor 265 is N2, the rotation speed of the first fan motor 165 is N2', and the rotation of the third fan motor 335 is N2'. The number may be N2''.

As described in the dual mode, the rotation speed N2 ′ of the first fan motor 165 may be greater than the rotation speed N2 of the second fan motor 265 .

In addition, the rotation speed N2 ″ of the third fan motor 335 may be the same as or higher than the rotation speed N2 of the second fan motor 265 . If the N2 is greater than the N2'', the air volume discharged from the upper module 200 is large and the air volume discharged through the flow control device 300 is relatively small. The discharged air tends to be directed upward only, and the amount of air flowing toward the front or rear of the air purifier 10 may be reduced. As a result, there may be a problem in that the discharge air is restricted from reaching a long distance from the air purifier 10 .

Therefore, in this embodiment, by maintaining the N2'' to be greater than or equal to N2, the tendency of the air to be discharged upward is small and the tendency to be discharged toward the front upper side or the rear upper side through the flow control device 300 is large. can be lost As a result, there is an advantage that the discharged air can reach a long distance from the air purifier 10 .

Similarly, even if the selected air volume is “medium wind” or “strong wind”, the rotation speed of the third fan motor 335 may be controlled to be greater than or equal to the rotation speed of the second fan motor 265 ( S15 ).

If the selected operation mode is the automatic operation mode in step S12, the concentration of dust or gas contained in the air of the clean space is detected through the sensor device 237, and the air quality level, that is, the air pollution level, is recognized according to the detected result. It can be (S16, S17).

Based on the recognized air pollution level, the controller 700 may determine a module to be operated or an air volume. In detail, as the level of the air pollution degree increases, the number of operated devices among the plurality of air cleaning modules 100 and 200 and the flow control device 300 may increase.

For example, when the level related to the air pollution degree is relatively low, that is, when the pollution level is in a "good state" or "normal state", the control unit 700 controls the first air cleaning module 100 to operate. The air purifier 10 can be controlled.

On the other hand, when the level related to the air pollution degree is an intermediate level, that is, when the pollution level is "bad state", the control unit 700 controls the air purifier ( 10) can be controlled.

And, when the level of the air pollution level is high, that is, when the pollution level is "very bad", the control unit 700 controls the first and second air cleaning modules 100 and 200 and the flow control device 300. It is possible to control the air purifier 10 to operate.

In this case, the air volume of the driven module may be preset to “weak wind”, but when the air volume input unit 717 is input, the air volume of the driven module may be changed. In addition, the rotation speed of the fan motors 165 , 265 , and 335 corresponding to each air volume may be controlled according to the method described in S15 ( S18 ).

16 is a view showing air flow when only the lower module of the air purifier is driven according to an embodiment of the present invention.

Referring to FIG. 16 , the air purifier 10 according to the embodiment of the present invention may be controlled to operate only the lower module 100 . For example, among the operation modes of the air purifier 10 , these operations may be possible in a manual operation mode and an automatic operation mode, respectively.

When the lower module 100 is operated, air in the clean space may be sucked into the lower module 100 through the first suction unit 102 . The sucked polluted air may be purified while passing through the first filter member 120 , and may be discharged into the clean space through the first fan 160 and the first discharge unit 105 .

Since one of the three modules provided in the air purifier 10 is operated, the amount of air circulated through the air purifier 10, that is, the purifying ability may be relatively small. Accordingly, when the clean space is relatively small, for example, when cleaning a small room, the user may select the manual operation mode and perform the single mode. For example, the cleaning ability of the air purifier 10 may have Q1 (m3) per minute. Of course, the cleaning ability Q1 may vary somewhat depending on the rotation speed of the first fan 160 .

17 is a view showing an air flow when the upper module and the lower module of the air purifier according to an embodiment of the present invention are driven.

The air purifier 10 according to an embodiment of the present invention may be controlled such that the lower module 100 and the upper module 200 are operated. For example, among the operation modes of the air purifier 10 , such operation may be possible in a manual operation mode and an automatic operation mode, respectively.

When the lower module 100 and the upper module 200 are operated, they may be respectively sucked into the lower module 100 and the upper module 200 through the first and second suction units 102 and 202 . The polluted air sucked into the lower module 100 may be purified while passing through the first filter member 120 , and may be discharged into a clean space through the first fan 160 and the first discharge unit 105 . .

In addition, the polluted air sucked into the upper module 200 may be purified while passing through the second filter member 220 , and may pass through the second fan 260 . And, the flow control device 300 is in the lying first position, the third fan 330 is rotated at a set number of revolutions, applying a blowing force to the air discharged from the second fan 260, It may be discharged through the second discharge unit 305 .

Since two modules out of three modules provided in the air purifier 10 are operated, the amount of air circulated through the air purifier 10, that is, the purifying ability, is relatively higher compared to the case where only the lower module 100 is operated. can be large Accordingly, when the clean space is relatively large, for example, when cleaning a large room, the user may select the manual operation mode and perform the dual mode. For example, the cleaning ability of the air purifier 10 may have Q2 (m3) per minute. Of course, the cleaning ability Q2 may vary slightly depending on the rotational speeds of the first and second fans 160 and 260 and the third fan 330 . In addition, the cleaning capability Q2 may have a larger value than the cleaning capability Q1.

18 is a view showing an air flow state when the air cleaning module and the flow control device according to the embodiment of the present invention are driven.

The air purifier 10 according to an embodiment of the present invention may be controlled such that the lower module 100 and the upper module 200 and the flow control device 300 operate. For example, among the operation modes of the air purifier 10 , such operation may be possible in a manual operation mode and an automatic operation mode, respectively.

When the lower module 100 and the upper module 200 and the flow control device 300 are operated, the lower module 100 and the upper module 200 are respectively directed to the lower module 100 and the upper module 200 through the first and second suction units 102 and 202. can be inhaled. The polluted air sucked into the lower module 100 may be purified while passing through the first filter member 120 , and may be discharged into a clean space through the first fan 160 and the first discharge unit 105 . .

Then, the polluted air sucked into the upper module 200 is purified while passing through the second filter member 220 , and is discharged into the clean space through the second discharge unit 305 through the second fan 260 . can At this time, since the third fan 330 of the flow control device 300 can be driven together, the air that has passed through the second fan 260 passes through the third fan 330 with a stronger blowing force. can have

The flow control device 300 may have an upward rotational movement by the second guide mechanism and may be inclined upwardly of the second module 200 . Accordingly, air may be discharged toward the upper side with respect to the air purifier 10 . Accordingly, clean air can be discharged from the air purifier 10 to a relatively long distance.

And, since the flow control device 300 performs a movement (refer to A of FIG. 11 ) to rotate in the left and right direction by the first guide mechanism, the air purifier 10 is divided into a left area and a right area based on the air purifier 10 . Clean air can be discharged.

Since all three modules provided in the air purifier 10 are operated, the amount of air circulated through the air purifier 10, that is, the cleaning ability, is determined when only the lower module 100 is operated, or the upper and lower modules 100 and 200 are Compared to the case of driving, it may be relatively large. Accordingly, when the clean space is relatively large, for example, when cleaning of an office or a large living room (room) is performed, the user may select the manual operation mode and perform the circulation mode.

For example, the cleaning ability of the air purifier 10 may have Q3 (m3) per minute. Of course, the cleaning ability Q3 may vary somewhat depending on the rotation speed of the first fans 160 , 260 , and 330 . In addition, the cleaning capability Q3 may have a larger value than the cleaning capability Q1 or Q2.

According to the operation of the air purifier, there is an advantage that the operation of the air purifier optimized according to the size of a clean space or the degree of air pollution is possible.

10: air purifier 20: base
100: blower 100: first blower
101: first case 110: suction grill
120: first filter member 130: first filter frame
140: support device 142: lever device
150: first fan housing 160: first fan
170: first air guide device 180: second air guide device
190: first discharge guide device 200: second blower device
201: second case 220: second filter member
230: second filter frame 237: sensor device
260: second fan 270: third air guide device
280: second discharge guide device 300: flow control device
310: third fan housing 320: flow guide part
330: third fan 600: display device
700: control unit 710: input unit
711: power input unit 713: operation mode input unit
715: clean mode input unit 717: air volume input unit

Claims (25)

a blowing fan, a filter member, and air passing through the blowing fan is discharged, each having a discharge unit provided on the upper portion to discharge purified air to the upper portion, and a lower air cleaning module and an upper air cleaning module stacked in a vertical direction;
a flow control device rotatably provided on the upper side of the upper air cleaning module and including a circulation fan for introducing the air discharged from the discharge unit of the upper air cleaning module;
A command regarding an operation mode is input for operation of the upper and lower air cleaning modules or the flow control device, and a clean mode input unit that determines the number of devices to be operated among the upper and lower air cleaning modules and the flow control device and an input unit including an air volume input unit capable of determining an air volume discharged from the device to be operated;
a control unit for controlling operations of the air cleaning module and the flow control device based on the operation mode input from the input unit; and
and a rotation guide device for guiding the left and right rotation of the flow control device and vertical rotation such that the flow control device is positioned at a first position or a second position,
The driving mode is
a single mode in which the lower air cleaning module is operated independently;
a dual mode in which the lower air purifying module and the upper air purifying module are operated together; and
and a circulation mode in which the upper and lower air cleaning modules and the flow control device are operated together,
When the operation mode is a single mode or a dual mode, the flow control device moves to the first position and the air passing through the circulation fan is discharged directly above the air cleaning module,
When the operation mode is the circulation mode, the operation of the flow control device is a case in which the flow control device is operated at the second position, and the flow control device moves to the second position and transfers the air passing through the circulation fan to the first position. Dispense obliquely in an inclined direction,
When the operation mode is determined to be the dual mode through the clean mode input unit, the air volume discharged from the upper and lower air purification modules is determined through the air volume input unit. As a result, the rotational speed of the blowing fans of the upper and lower air purification modules and an air purifier in which the rotation speed of the circulation fan of the flow control device is controlled.
The method of claim 1,
In the dual mode, the control unit,
The air purifier according to claim 1, wherein the rotation speed of the first fan of the lower air cleaning module is controlled to be greater than the rotation speed of the second fan of the upper air cleaning module. 3. The method of claim 2,
In the dual mode, the control unit,
The air cleaner according to claim 1, wherein the rotation speed of the circulation fan is controlled to be the same as the rotation speed of the second fan. The method of claim 1,
In the circulation mode, the control unit,
The air purifier according to claim 1, wherein the rotation speed of the circulation fan is controlled to be the same as or higher than that of the second fan of the upper air purifying module. 5. The method of claim 4,
When the operation mode is determined to be the circulation mode through the clean mode input unit, the control unit controls the flow control device to be positioned at the second position. 6. The method of claim 5,
In the circulation mode, the control unit,
The air purifier according to claim 1, wherein the rotation speed of the first fan of the lower air purifying module is controlled to be greater than the rotation speed of the second fan. The method of claim 1,
The flow regulating device in the second position is an air purifier positioned to be inclined upward by a set angle with respect to the flow regulating device in the first position. 8. The method of claim 7,
The upper air cleaning module includes an upper discharge grill that guides the discharge of air that has passed through the second fan of the upper air cleaning module,
The flow control device is located above the upper discharge grill, the air purifier comprising an inlet grill through which the air discharged from the upper discharge grill is introduced.
9. The method of claim 8,
When the flow control device is in the second position, at least a portion of the inlet grill of the flow control device is an air purifier disposed to be spaced apart upward from the upper surface of the upper discharge grill. 10. The method of claim 9,
In the circulation mode, the control unit,
The air purifier according to claim 1, wherein the rotation speed of the circulation fan is controlled to be greater than or equal to the rotation speed of the second fan of the upper air purifying module.
The method of claim 1,
In the dual mode, the air discharged through the discharge unit of the lower air cleaning module flows in a horizontal direction and the air discharged through the discharge unit of the upper air cleaning module is provided such that the air flows directly upward. 12. The method of claim 11,
Further comprising a partition plate positioned between the upper air cleaning module and the lower air cleaning module,
The partition plate is an air purifier provided such that the upper air purifying module and the lower air purifying module are vertically spaced apart. 13. The method of claim 12,
An upper separation space is formed between the partition plate and the upper air cleaning module,
A lower separation space is formed between the partition plate and the lower air cleaning module,
The lower separation space is an air purifier forming a discharge passage for air discharged from the discharge unit of the lower air cleaning module. 14. The method of claim 13,
In the driving mode,
a manual operation mode in which a device to be operated and an air volume can be selected from among the air cleaning module and the flow control device; and
and an automatic operation mode for determining a device to be operated from among the air cleaning module and the flow control device according to the degree of pollution detected by the sensor device. 15. The method of claim 14,
The lower air cleaning module sucks air in a radial direction and discharges it radially through the lower separation space,
The upper air purifying module is an air purifier that sucks air in a radial direction and discharges it toward the flow control device. The method of claim 1,
When the flow control device is positioned at the second position, the control unit selectively controls the flow control device to rotate in the left and right directions based on the axial direction of the blower fan. a blowing fan, a filter member, and air passing through the blowing fan is discharged, each having a discharge unit provided on the upper portion to discharge purified air to the upper portion, and a lower air cleaning module and an upper air cleaning module stacked in a vertical direction;
a flow control device rotatably provided on the upper side of the upper air cleaning module and including a circulation fan for introducing the air discharged from the discharge part of the upper air cleaning module;
an input unit for inputting an input regarding an operation mode for operation of the upper and lower air cleaning modules or the flow control device;
a control unit for controlling the operation of the upper and lower air cleaning modules and the flow control device based on the operation mode input from the input unit; and
A rotation guide device for guiding the left-right rotation of the flow control device and the vertical rotation such that the flow control device is positioned at a first position or a second position,
The driving mode is
a single mode in which the lower air cleaning module is operated independently;
a dual mode in which the lower air purifying module and the upper air purifying module are operated together; and
and a circulation mode in which the upper and lower air cleaning modules and the flow control device are operated together,
When the operation mode is the single mode or the dual mode, the flow control device moves to the first position and the air passing through the circulation fan is discharged directly above the upper air cleaning module,
When the operation mode is the circulation mode, the flow control device is operated at the second position, and the flow control device moves to the second position so that the air passing through the circulation fan is moved to the first position. It is discharged obliquely in an inclined direction with respect to
The blowing fan of the air purifying module includes a first fan provided in the lower air purifying module and a second fan provided in the upper air purifying module,
The input unit includes an air volume input unit capable of determining the air volume of the blowing fan and the circulation fan according to the input mode among the single mode, the dual mode and the circulation mode.
18. The method of claim 17,
When the operation mode is the single mode, when the air volume of the blowing fan is determined as a weak wind among the air volumes of the blowing fans that can be determined through the air volume input unit, the blowing fan is operated at a set speed corresponding to the weak wind, and the The circulation fan of the flow control device is an air purifier controlled in an off state. 19. The method of claim 18,
Among the blowing fans, the first fan of the lower air purifying module is operated at a set speed corresponding to the weak wind and the second fan of the upper air purifying module is controlled in an off state. 18. The method of claim 17,
When the operation mode is the dual mode, if the air volume of the blowing fan is determined through the air volume input unit as a medium wind or a strong wind stronger than a weak wind among the air volumes of the blowing fan that can be determined, the first fan and the second fan are The air purifier is operated at a set speed corresponding to the determined air volume, and the circulation fan is controlled at a set speed according to the determined air volume of the blowing fan. 21. The method of claim 20,
The circulation fan is an air purifier controlled to operate at the same speed as the second fan of the upper air purifying module among the blowing fans. 19. The method of claim 18,
When the operation mode is the dual mode, the circulation fan is controlled to be in an off state. 23. The method of claim 22,
When the operation mode is the dual mode, the air volume of the second fan of the upper air purifying module is determined as a weak wind among the air volumes that can be determined through the air volume input unit. 21. The method of claim 20,
When the air volume of the blowing fan is determined through the air volume input unit as a medium wind or strong wind stronger than the weak wind among the air volumes of the blowing fan that can be determined, the circulation fan is controlled at a different speed according to the determined air volume of the blowing fan. . 25. The method of claim 24,
When the operation mode is the dual mode, the circulation fan is controlled at the same speed as the second fan of the upper air cleaning module among the blowing fans.

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