KR20220110709A - Cleaner station, cleaner system including same, and residual dust removal method using the cleaner system - Google Patents

Abstract

Disclosed are a cleaner station configured to suck in the dust stored in a cleaner, a cleaner system including the same, and a method for removing residual dust using the cleaner system. According to the present invention, it is possible to effectively suck in the residual dust accumulated in the vicinity of a push protrusion inside the cleaner station through a bypass hole provided to pierce through the outside and inside of a suction tube. Furthermore, the present invention makes it possible to effectively remove the residual dust accumulated inside of a coupling lever installed on the outside of a dust canister of the cleaner through a dust discharge groove formed on the coupling lever.

Description

A cleaner station and a cleaner system including the same, and a residual dust removal method using the cleaner system {Cleaner station, cleaner system including same, and residual dust removal method using the cleaner system}

The present invention relates to a cleaner station for sucking dust stored in the cleaner, a cleaner system including the same, and a method for removing residual dust using the cleaner system. The present invention relates to a cleaner station and a cleaner system including the same, having a structure capable of removing residual dust accumulated in the cleaner station after the exhaust cover of the dust container is closed by sucking all the dust in, and a method for removing residual dust using the cleaner system It is an invention that discloses

In general, a vacuum cleaner is a household appliance that sucks small garbage or dust and fills a dust bin in a product by sucking air using electricity, and is generally referred to as a vacuum cleaner.

Such a vacuum cleaner may be divided into a manual cleaner in which a user directly moves the cleaner and performs cleaning, and an automatic cleaner in which the user performs cleaning while driving by themselves. Manual vacuum cleaners may be classified into canister-type cleaners, upright cleaners, handy-type cleaners, stick-type cleaners, and the like, depending on the type of cleaner.

In the past, canister-type vacuum cleaners were used a lot in household cleaners, but recently, hand-held vacuum cleaners and stick cleaners, which are convenient to use by providing a dust container and a cleaner body, are increasingly used.

The canisty type vacuum cleaner is connected to the main body and the suction port by a rubber hose or pipe, and in some cases, it can be used by inserting a brush into the suction port.

The handheld vacuum cleaner maximizes portability, and although it is light in weight, there may be restrictions on the cleaning area while sitting due to its short length. Therefore, it is used to clean localized places such as on a desk or sofa, or in a car.

The stick vacuum cleaner can be used while standing, so you can clean without bending your back. Therefore, it is advantageous for cleaning while moving a large area. If a hand-held vacuum cleaner cleans a narrow space, the stick-type vacuum cleaner can clean a wider space than that, and can clean a high place that cannot be reached by hand. Recently, a stick cleaner is provided in a module type, and the cleaner type is actively changed and used for various objects.

However, in the stick cleaner, the capacity of the dust bin for storing the collected dust is small, so that the user has to empty the dust bin every time.

As a prior patent document, Korean Patent Laid-Open Publication No. 10-2020-0074001 discloses a cleaning device including a vacuum cleaner and a docking station.

The prior patent document includes a vacuum cleaner including a dust collector in which foreign substances are collected, and a docking station connected to the dust collector to remove foreign substances collected in the dust collector, and the dust collector is docked to the docking station. The docking station is configured to include a suction device for sucking foreign substances and internal air in the dust collector docked in the docking station.

In addition, the prior patent document is configured to include a collecting unit for collecting foreign substances inside the docking station.

However, the prior patent document has a problem in that after the suction of the suction device (suction fan) is finished, foreign substances that may stick to the periphery of the dust collector during the suction process cannot be removed.

Therefore, when the user uses the vacuum cleaner again after the suction process of the foreign material is finished, the user has no choice but to touch the foreign material (hereinafter, residual dust) that is exposed while sticking around the dust collector, and the user It is inconvenient to have to remove the residual dust directly using a wet tissue or the like.

In addition, when these foreign substances are deposited inside the docking station, there is a problem that the inside of the docking station is contaminated.

Korean Patent Publication No. 10-2020-0074001

An object of the present invention is to provide a cleaner station configured to effectively remove residual dust accumulated outside a dust box of the cleaner or inside the cleaner station during a dust suction process of the cleaner station.

Another object of the present invention is to provide a method for effectively removing residual dust by using a cleaner system including the cleaner and the cleaner station.

In order to solve the above problems, a cleaner station according to an embodiment of the present invention includes: a housing coupled to the cleaner; a coupling part in which one side of the housing is recessed toward the inside of the housing, and to which at least a portion of the cleaner is coupled; a cover opening unit disposed in the coupling portion and configured to open a discharge cover of the dust container of the cleaner; a dust collecting motor accommodated in the housing and generating a suction force for sucking dust inside the dust bin of the cleaner; and a suction pipe disposed in the vertical direction inside the housing and having one end connected to the coupling part, wherein the cover opening unit is configured to open the discharge cover when the cleaner is coupled to the coupling part. and a push protrusion formed to protrude in the long axis direction of the housing at a position opposite to the coupling lever of the discharge cover, and in the suction pipe, a long hole shape at a position where the push protrusion faces the push protrusion in a direction in which the push protrusion presses the coupling lever is formed, and a bypass hole passing through the inside and outside of the suction pipe is provided.

In addition, a door hinged to the coupling portion and opened in a direction in which the discharge cover is opened to communicate the outside of the housing with the suction pipe, and a door arm coupled to the door to open and close the door. unit; the dust collecting motor may generate suction force by driving for a predetermined period of time in a state in which the dust bin is coupled to the coupling part after the door is closed by the door unit.

In this case, the cover opening unit, coupled to the lower end of the push protrusion, a protrusion support that linearly reciprocates with the push protrusion; may further include.

The coupling part may include: a first coupling part corresponding to the shape of the dust container and provided to support a portion of a lower outer circumferential surface of the dust container; and a second coupling part coupled to the first coupling part and including a flat surface on which the lower surface of the protrusion supporter is disposed so as to reciprocate in a straight line.

Here, when the direction in which the protrusion supporter linearly reciprocates is referred to as a first direction, and a direction perpendicular to the first direction is referred to as a second direction, the size of the second direction of the protrusion supporter is the size of the flat surface. It may be provided smaller than the size in the second direction.

In addition, a movement axis of the protrusion support may be disposed at a center of the flat surface in the second direction.

Meanwhile, a cleaner station according to an embodiment of the present invention includes: a housing coupled to the cleaner; One side of the housing is formed to be recessed toward the inside of the housing, and at least a portion of the cleaner is coupled, and when the cleaner is coupled, it includes a dust passage hole formed at a position opposite to the dust container of the cleaner. wealth; a dust collecting motor accommodated in the housing and generating a suction force for sucking dust in the dust container; and a suction pipe disposed in the vertical direction inside the housing and having one end connected to the coupling part to communicate with the dust passage hole; A bypass hole is provided, and the bypass hole is formed to have a cross-sectional area smaller than a cross-sectional area passed through the dust passage hole.

The cover opening unit may further include a cover opening unit disposed in the coupling part and configured to open a discharge cover of the dust bin, wherein the cover opening unit is configured to open the discharge cover when the cleaner is coupled to the coupling part. and a push protrusion formed to protrude in the long axis direction of the housing at a position opposite to the coupling lever of can

In addition, a door hinged to the coupling portion and opened in a direction in which the discharge cover is opened to communicate the outside of the housing with the suction pipe, and a door arm coupled to the door to open and close the door. unit; further, the dust collecting motor may generate suction force in the bypass hole by driving for a predetermined time after the door closes the dust passage hole by the door unit.

On the other hand, a cleaner system according to an embodiment of the present invention is a cleaner system including a cleaner including a dust container for collecting dust, and a cleaner station coupled to the cleaner to remove dust discharged from the dust container, The dust bin may include: a dust bin body having a cylindrical shape and having an open side; a discharge cover rotatably coupled to one open side of the dust container body and including a coupling hook hook-coupled to the dust container body; and a coupling lever coupled to the dustbin body and moving along an outer circumferential surface of the dustbin body in the longitudinal direction of the dustbin body to release the hook coupling between the discharge cover and the dustbin body, wherein the coupling lever comprises: a lever body extending along the length direction of the dust container body; and a lever inclination part connected to the lever body and extending upwardly inclined at a predetermined angle with respect to the moving direction of the coupling lever, wherein the lever inclined part has one end of the lever inclined part It is characterized in that the dust discharge groove recessed toward the is provided.

In this case, the cleaner station may include: a housing coupled to the cleaner; a coupling part in which one side of the housing is recessed toward the inside of the housing, and to which at least a portion of the cleaner is coupled; a suction pipe disposed in the vertical direction inside the housing and having one end connected to the coupling part; and a push protrusion formed to protrude in the long axis direction of the housing at a position opposite to the coupling lever to open the discharge cover when the cleaner is coupled to the coupling part, wherein the suction pipe includes the push protrusion having the coupling It is formed in the form of a long hole at a position facing the push protrusion in the direction of pressing the lever, and a bypass hole penetrating the inside and the outside of the suction pipe may be provided.

In this case, a cross-sectional area through which the suction pipe is connected to one end connected to the coupling part may be larger than a cross-sectional area through which the bypass hole is penetrated.

The cleaner station may include: a dust collecting motor accommodated in the housing and generating a suction force for sucking dust in the dust bin of the cleaner; and a door hinged to the coupling portion and opened in a direction in which the discharge cover is opened to communicate the exterior of the housing with the suction pipe, and a door arm coupled to the door to open and close the door. The dust collecting motor may generate suction force by driving for a predetermined period of time in a state in which the dust container is coupled to the coupling part after the door is closed by the door unit.

A method for removing residual dust using a cleaner system according to an embodiment of the present invention includes a cleaner including a dust container for collecting dust, and a cleaner system including a cleaner station coupled to the cleaner to remove dust discharged from the dust container. A method for removing residual dust, comprising: a door opening step of opening a door provided in the cleaner station to communicate with the outside and the inside of the cleaner station; a discharge cover opening step of opening a discharge cover for opening and closing the dust container; a dust collecting step in which the dust inside the dust bin is sucked into the cleaner station by driving a dust collecting motor accommodated in the cleaner station; a door closing step of closing the door together with the discharge cover; and a residual dust removing step of removing residual dust present in the vicinity of the dust bin after the door closing step, wherein the residual dust removing step includes: By re-driving for a predetermined period of time, the residual dust is sucked into the cleaner station.

In this case, the cleaner station may include: a housing coupled to the cleaner; a coupling part in which one side of the housing is recessed toward the inside of the housing, and to which at least a portion of the cleaner is coupled; a suction pipe disposed in the vertical direction inside the housing and having one end connected to the coupling part; and a push protrusion formed to protrude in the long axis direction of the housing at a position opposite to the coupling lever of the discharge cover to open the discharge cover when the cleaner is coupled to the coupling part, wherein the suction pipe has the push protrusion is formed in the form of a long hole at a position facing the push protrusion in the direction of pressing the coupling lever, a bypass hole penetrating the inside and the outside of the suction pipe is provided, and the residual dust removal step includes the dust collecting motor During driving, the residual dust may be sucked into the suction pipe through the bypass hole.

The discharge cover may be hook-coupled to a cylindrical dust container body included in the dust container, and the coupling lever may include a lever body extending in a longitudinal direction of the dust container body; and a lever inclination portion connected to the lever body and extending upwardly inclined at a predetermined angle with respect to the moving direction of the coupling lever, wherein the lever inclined portion has one end of the lever inclined portion A dust discharging groove recessed toward is provided, and in the step of removing the residual dust, the residual dust may be sucked into the suction pipe through the dust discharging groove and the bypass hole while the dust collecting motor is re-driven.

According to the present invention, residual dust accumulated in the vicinity of the push protrusion inside the cleaner station can be effectively sucked through the bypass hole provided to penetrate the outside and the inside of the suction pipe.

Further, according to the present invention, residual dust accumulated inside the coupling lever outside the dust box of the cleaner can be effectively removed through the dust discharge groove formed in the coupling lever of the cleaner.

In addition, according to the present invention, the suction force for sucking the residual dust is transferred to the bypass hole and the by-pass hole through the residual dust removal step of re-driving the dust collecting motor for a predetermined time after the suction of the dust inside the dust bin is finished and the discharge cover is closed. Since it can be concentrated into the dust outlet groove, residual dust can be removed more effectively.

1 is a perspective view illustrating a cleaner system including a cleaner station and a cleaner according to an embodiment of the present invention.
2 is a view showing a shape in which the cleaner is coupled to the cleaner station and the inside of the side surface of the cleaner station.
3 is an enlarged view of the dust container opening and closing structure of the vacuum cleaner.
4 is an enlarged view of a cover opening unit of the cleaner station.
5 is an enlarged view of the door unit of the cleaner station.
6 is an enlarged perspective view of a cross-section of a coupling part and a suction pipe.
7 is a view looking down the coupling portion from the top.
8 is a cross-sectional view of a state in which the cleaner is coupled to the coupling part.
9 is a perspective view of a coupling lever of the cleaner;
10 is a perspective view of the coupling lever of FIG. 9 viewed from another direction.
11 is a side view of the engagement lever of FIG. 9 ;
12 is a perspective view illustrating a relationship between a direction in which a lever inclined portion of a coupling lever is formed and a movement direction of the push protrusion;
13 is a schematic diagram of a suction path of residual dust through a dust removal groove and a bypass hole of a coupling lever;
14 is a flowchart of a method for removing residual dust using a cleaner system according to an embodiment of the present invention.

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

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and will be described in detail in the detailed description. This is not intended to limit the present invention to a specific embodiment, it should be construed to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

In describing the present invention, terms such as first and second may be used to describe various components, but the components may not be limited by the terms. The above terms are only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component.

The term “and/or” may include a combination of a plurality of related listed items or any of a plurality of related listed items.

When a component is referred to as being “connected” or “connected” to another component, it may be directly connected or connected to the other component, but other components may exist in between. can be understood On the other hand, when it is mentioned that a certain element is "directly connected" or "directly connected" to another element, it may be understood that the other element does not exist in the middle.

The terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression may include the plural expression unless the context clearly dictates otherwise.

In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, and one or more other features It may be understood that the existence or addition of numbers, steps, operations, components, parts or combinations thereof is not precluded in advance.

Unless defined otherwise, all terms used herein, including technical or scientific terms, may have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary may be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the present application, it is interpreted in an ideal or excessively formal meaning. it may not be

In addition, the following embodiments are provided to more completely explain to those with average knowledge in the art, and the shapes and sizes of elements in the drawings may be exaggerated for clearer explanation.

1 is a perspective view illustrating a cleaner system 1000 including a cleaner station 1 and a cleaner 2 according to an embodiment of the present invention, and FIG. 2 is a shape in which the cleaner 2 is coupled to the cleaner station 1 and a view showing the inside of the side surface of the cleaner station 1 , FIG. 3 is an enlarged view of the opening and closing structure of the dust container 2600 of the cleaner 2 , and FIG. 4 is an enlarged view of the cover opening unit 500 of the cleaner station 1 . FIG. 5 is an enlarged view of the door unit 600 of the cleaner station 1 .

Referring to FIG. 1 , a cleaner system 1000 may include a cleaner station 1 and a cleaner 2 .

The cleaner station 1 is configured to be coupled to the cleaner 2 to remove dust discharged from the dust container 2600 of the cleaner 2 , and the cleaner 2 may be coupled to the front of the cleaner station 1 . More specifically, the cleaner body 2000 of the cleaner 2 may be coupled to the front of the cleaner station 1 .

At this time, the front in the cleaner station 1 means that the coupling part 110 is formed in such a way that one side of the housing 100 is depressed toward the inside of the housing 100 so that the main body of the cleaner 2 can be coupled. direction can be defined. In addition, a direction in which the opposite surface of the housing 100 faces with respect to the coupling part 110 may be defined as a rearward direction. The structure of the housing 100 will be described later.

Hereinafter, a configuration of the cleaner body 2000 of the cleaner 2 coupled to the cleaner station 1 according to an embodiment of the present invention will be briefly described.

Referring to FIG. 2 , the cleaner body 2000 communicates with the suction unit 2100 and the suction unit 2100 that provide a flow path through which the air containing dust can flow, and is sucked into the inside through the suction unit 2100 . It may include a dust separation unit 2200 for separating the dust, a suction motor 2300 for generating a suction force for sucking air, a handle 2400 held by the user, and a battery housing 2500 for accommodating the battery therein. can

Also, the cleaner body 2000 may further include a dust container 2600 .

Here, the dust container 2600 may communicate with the dust separator 2200 and collect dust separated from the dust separator 2200 . The dust separator 2200 may be configured to separate dust by a cyclone dust collection method.

Referring to FIG. 3 , the dust container 2600 may include a dust container body 2610 , a discharge cover 2620 , and a coupling lever 2630 .

The dust container body 2610 may have a cylindrical shape and may be provided with one side open. The air introduced through the suction unit 2100 passes through the dust separation unit 2200 accommodated in the dust bin body 2610. At this time, the dust is collected inside the dust bin body 2610 and the air from which the dust is separated is transferred to the suction motor ( 2300) and discharged to the outside of the cleaner (2). The dustbin body 2610 may be provided with a body jaw 2650 having the dustbin body 2610 extending in the longitudinal direction from both sides between the coupling levers 2630 .

The discharge cover 2620 may be rotatably coupled to an open side of the dust container body 2610 . More specifically, the discharge cover 2620 may be coupled to the dustbin body 2610 using the dustbin hinge 2640 as a medium at one open side of the dustbin body 2610 . In this case, the dustbin hinge 2640 may be disposed on one side close to the battery housing 2500 . The discharge cover 2620 may rotate to open or close the dustbin body 2610 with the dustbin hinge 2640 as an axis.

Also, the discharge cover 2620 may include a coupling hook 2660 that is hook-coupled to the dust container body 2610 on one side close to the suction unit 2100 . The coupling hook 2660 and the dustbin hinge 2640 may be disposed opposite to each other.

The coupling lever 2630 may be provided to move along the outer circumferential surface of the dustbin body 2610 in the longitudinal direction of the dustbin body 2610 to release the hook coupling between the discharge cover 2620 and the dustbin body 2610. . The coupling lever 2630 may be disposed downward based on a state in which the cleaner 2 is coupled to the cleaner station 1 . When an external force is applied to the coupling lever 2630 and the coupling lever 2630 moves in the longitudinal direction (the direction to release the hook coupling) of the dust container body 2610, the coupling hook provided in a form extending from the discharge cover 2620 ( As the 2660 is elastically deformed, the hook coupling between the discharge cover 2620 and the dust container body 2610 may be released.

On the other hand, according to an embodiment of the present invention, the coupling lever 2630 may be provided to have a shape for efficiently removing residual dust introduced into the inside of the coupling lever 2630 during the dust suction process of the cleaner station 1 . , which will be described later in detail. Here, the inside of the coupling lever 2630 may mean a space between the coupling lever 2630 and the dust container body 2610 .

Next, the cleaner station 1 according to the embodiment of the present invention will be described.

Referring to FIG. 2 , the cleaner station 1 may include a housing 100 , a dust collecting motor 200 , and a dust storage module 300 .

The housing 100 is a configuration to which the cleaner 2 is coupled, and may form the exterior of the cleaner station 1 . Specifically, the housing 100 may be formed in a pillar shape including at least one outer wall surface. For example, the housing 100 may be formed in a shape similar to a square pole.

The housing 100 has a space formed therein to accommodate the dust collecting motor 200 , the dust storage module 300 , and the like.

The housing 100 may include a ground support part 100e. In this case, the ground support part 100e may be disposed toward the ground. The bottom surface of the ground support part 100e in contact with the ground may be disposed parallel to the ground, and may be disposed at an angle to the ground at an inclined angle. With such a configuration, the dust collecting motor 200 accommodated in the housing 100 can be stably supported, and even when the cleaner 2 is coupled, the overall weight can be balanced.

In addition, the ground support part 100e may be in the form of a plate extending from the bottom surface of the housing 100 to prevent the cleaner station 1 from falling down, to maintain balance, and to increase an area in contact with the ground.

Meanwhile, the housing 100 may be configured to include at least one outer wall surface as described above. For example, the housing 100 may include a first outer wall surface 100a on which the coupling portion 110 is formed, and the first outer wall surface 100a is disposed in a counterclockwise direction in a state facing the first outer wall surface 100a. The second outer wall surface 100b, the third outer wall surface 100c, and the fourth outer wall surface 100d may be further included.

The coupling part 110 formed on the first outer wall surface 100a may be formed in such a way that one side of the housing 100 is depressed toward the inside of the housing 100 . More specifically, the coupling part 110 may be provided in which the first outer wall surface 100a of the cleaner body 2000 is recessed to correspond to the shape of a portion in the direction in which the dust container 2600 is disposed. With this configuration, a portion of the cleaner body 2000 may be coupled to the cleaner station 1 and supported by the cleaner station 1 .

Meanwhile, the housing 100 may be provided to be openable so that some of the components accommodated therein (eg, the dust storage module 300 ) are exposed.

The dust collecting motor 200 may be accommodated in the housing 100 and disposed under the dust storage module 300 . The dust collecting motor 200 may generate a suction force to the suction pipe 700 to be described later. Through this, the dust collecting motor 200 may suck the dust inside the dust container body 2610 of the cleaner 2 (refer to FIG. 2 ).

Next, the dust storage module 300 is accommodated in the housing 100 , and collects dust sucked from the inside of the dust container 2600 of the cleaner 2 by the dust collecting motor 200 . The dust storage module 300 may be detachably coupled to the housing 100 .

Accordingly, when the housing 100 is opened, the dust storage module 300 may be separated from the housing 100 and disposed of, and a new dust storage module 300 may be coupled to the housing 100 . That is, the dust storage module 300 may be defined as a consumable part.

The dust storage module 300 may include a dust bag 310 . The dust bag 310 may be provided such that the dust is accommodated therein while increasing in volume when suction force is generated by the dust collecting motor 200 . To this end, the dust bag 310 may be made of a material that transmits air but does not transmit foreign substances such as dust. For example, the dust bag 310 may be made of a non-woven material and may have a hexahedral shape based on an increase in volume.

When an airflow is formed by the suction force of the dust collecting motor 200, the air containing foreign substances flowing from the inside of the dust container 2600 of the cleaner 2 moves to the dust bag 310 through the suction pipe 700, The dust bag 310 exits the dust bag 310 leaving only foreign substances in the dust bag 310 .

In addition, the dust storage module 300 may further include a dust storage housing 320 accommodated in the housing 100 and having an inner space to which the dust bag 310 is coupled. (See FIG. 2 )

Hereinafter, the coupling part 110 to which the cleaner 2 is coupled will be described with reference to FIGS. 5 and 6 .

6 is an enlarged perspective view of a cross section of the coupling part 110 and the suction pipe 700 .

Referring first to FIG. 6 , the coupling part 110 may include a first coupling part 111 and a second coupling part 112 . In this case, the first coupling part 111 may correspond to the shape of the dust container 2600 and may be provided to support a portion of the lower outer circumferential surface of the dust container 2600 . The second coupling part 112 is coupled to the first coupling part 111 and the lower surface of the protrusion support 512 included in the cover opening unit 500 to be described later is disposed on a flat surface provided to reciprocate in a straight line. (112a) may be included.

More specifically, the second coupling part 112 may be provided to extend downwardly from the first coupling part 111 to provide a space in which the push protrusion 511 can be accommodated. In this case, the first coupling part 111 may be disposed on the left and right sides of the second coupling part 112 based on the state viewed from the first outer wall surface 100a.

The first coupling portion 111 may include a curved portion 111a and a protrusion 111b. The curved portion 111a may be formed to correspond to the cylindrical shape of the dust container body 2610 to support the dust container body 2610 . In addition, the protruding jaw 111b is coupled to the curved portion 111a, the curved portion 111a extends upward and protrudes, and is configured to support the body jaw 2650 of the dust container body 2610. When the 2600 is seated on the coupling unit 110 , it may serve to fix the dust container body 2610 not to be shaken.

In this case, the curved portion 111a and the protruding jaw 111b may be provided in a symmetrical shape on the left and right sides of the second coupling portion 112 based on the state when the first outer wall surface 100a is viewed.

The second coupling part 112 may further include a vertical wall 112b extending downward from the first coupling part 111 . The vertical wall 112b may be disposed on the left and right sides of the flat surface 112a based on a state when viewed from the first outer wall surface 100a. That is, the second coupling portion 112 is composed of a vertical wall 112b extending downward from the end of the first coupling portion 111 and a flat surface 112a, so that the push protrusion 511 can linearly reciprocate. space can be formed. Meanwhile, on the flat surface 112a of the second coupling part 112 , a protrusion neck insertion hole 112aa for arranging a protrusion neck 513 to be described later may be provided.

Meanwhile, the coupling unit 110 may further include a third coupling unit 113 .

Referring to FIG. 5 , the third coupling part 113 may be defined as an area disposed to face the discharge cover 2620 based on a state in which the cleaner 2 is coupled to the cleaner station 1 . The third coupling part 113 includes a charging part (not shown) to which a battery is electrically coupled for charging of the cleaner 2, and a suction pipe (not shown) disposed under the charging part and disposed inside the dust container 2600 and the cleaner station 1 ( A dust passage hole 113a provided to communicate 700 may be included. A door hinge 605 may be coupled to the third coupling part 113 as an upper portion of the dust passage hole 113a. A door 610 coupled to the door hinge 605 may be disposed in the dust passage hole 113a to open or close the dust passage hole 113a. The dust passage hole 113a has a diameter corresponding to the diameter of the dust container 2600 at a position opposite to the bottom surface of the dust container 2600 of the cleaner 10 when the cleaner 2 is coupled to the coupling part 110 . It can be a hall to be Accordingly, the dust passage hole 113a may serve as a main hole for sucking the dust of the dust container 2600 into the internal flow path of the cleaner station 1 .

Next, with reference to FIG. 2 again, a combination of the cleaner station 1 and the cleaner 2 will be described.

As described above, the cleaner 2 may be coupled to the front of the housing 100 . More specifically, some components of the main body 2100 of the cleaner 2 may be coupled to the coupling part 110 so that the entirety of the cleaner 2 may be mounted on the cleaner station 1 . More specifically, when the cleaner 2 is coupled to the coupling part 110 of the housing 100 , the longitudinal axis of the dust container 2600 may be disposed parallel to the ground. Also, when the cleaner 2 is coupled to the coupling part 110 of the housing 100 , the longitudinal axis of the dust container 2600 may be disposed perpendicular to the long axis of the housing 100 . At this time, the vacuum cleaner 2 may be mounted so that the longitudinal axis of the suction unit 2100 of the cleaner 2 is parallel to the long axis of the housing 100 .

Meanwhile, as will be described later, the suction pipe 700 of the cleaner station 1 may extend vertically inside the housing 100 . Accordingly, the dust present in the dust container 2600 by the suction force of the dust collecting motor 200 moves in the horizontal direction along the dust container body 2610 and changes in the vertical direction as it enters the suction pipe 700 inside the housing 100 ) is collected in the dust storage module 300 accommodated in the inner lower side.

That is, dust in the dust container 2600 of the cleaner 2 may be collected by the dust storage module 300 of the cleaner station 1 by the suction force and gravity of the dust collecting motor 200 .

Through this configuration, it is possible to remove the dust in the dust bin without a separate operation by the user, thereby providing user convenience. In addition, it is possible to eliminate the hassle of the user having to empty the dust bin every time. In addition, when the dust bin is emptied, it is possible to prevent dust from scattering.

The cleaner station 1 according to the embodiment of the present invention may further include a cover opening unit 500 .

The cover opening unit 500 is provided to open the discharge cover 2620 of the cleaner 2 . Referring to FIG. 4 , the cover opening unit 500 may include a push protrusion 511 , a cover opening gear 520 , and a cover opening motor (not shown).

When the cleaner 2 is coupled to the coupling part 110 , the push protrusion 511 may linearly reciprocate on the coupling part 110 to press and open the discharge cover 2620 . More specifically, the push protrusion 511 may be disposed at a position where the coupling lever 2630 can be pressed on the coupling part 110 , and may reciprocate linearly to press the coupling lever 2630 . More specifically, the push protrusion 511 may be formed to protrude upward in the longitudinal direction of the housing at a position opposite to the coupling lever 2630 provided to open the discharge cover 2620 of the cleaner 2 .

The cover opening unit 500 may further include a protrusion support 512 , a protrusion neck 513 , and a gear coupling block 514 .

At this time, the protrusion support 512 is coupled to the lower end of the push protrusion 511 and linearly reciprocates with the push protrusion 511 , and the lower surface of the protrusion support 512 is flat of the second coupling part 112 . It is disposed to face the surface (112a) and the protrusion supporter 512 can linearly reciprocate on the flat surface (112a).

The protrusion neck 513 may be coupled to the lower surface of the protrusion support 512 and disposed in the protrusion neck insertion hole 112aa. The protrusion neck 513 may be coupled between the protrusion support 512 and the gear coupling block 514 . That is, the protrusion support 512 is coupled to the upper portion of the protrusion neck 513 and the gear coupling block 514 is coupled to the lower portion of the protrusion neck 513 to push the protrusion 511 to the upper portion of the flat surface 112a. ) and the protrusion support 512 are exposed and a gear coupling block 514 may be disposed under the flat surface 112a. The protrusion neck 513 may be formed to have a narrower width than the protrusion support 512 and the gear coupling block 514 .

The gear coupling block 514 is disposed under the flat surface 112a and may reciprocate linearly by the movement of the cover opening gear 520 .

The cover opening motor may provide power for linearly reciprocating the push protrusion 511 to the cover opening gear 520 . More specifically, the cover opening gear 520 is coupled with the cover opening motor, and using the power of the cover opening motor, the push projection 511, the projection support 512, the projection neck 513 and the gear coupling block 514. can be moved together. The cover opening gear 520 is meshed with the first cover opening gear 521 and the first cover opening gear 521 receiving rotational power from the shaft of the cover opening motor and transmitting a linear reciprocating motion to the push protrusion 511. A second cover opening gear 522 may be included.

In this case, the first cover opening gear 521 may be formed of a pinion gear, and the second cover opening gear 522 may be formed of a rack gear.

In other words, when the main body of the cleaner 2 is fixed to the coupling part 110 , the cover opening motor moves the push protrusion 511 through the cover opening gear 520 and opens the discharge cover 2620 to open the dust container body. (2610).

The cleaner station 1 according to the embodiment of the present invention may further include a door unit 600 .

Referring to FIG. 5 , the door unit 600 may include a door 610 , a door arm 620 , and a door motor 630 .

The door 610 may be hinge-coupled to the coupling part 110 , and may be opened in a direction in which the discharge cover 2620 is opened to communicate the outside of the housing 100 with the suction pipe 700 . More specifically, the door 610 is coupled to the door hinge 605 disposed on the third coupling part 113 to be rotatable around the door hinge 605 .

When the door 610 pulls the door 610 in a state where the door 610 closes the dust passage hole 113a to close the inside and outside of the housing 100 , the door 610 opens the vacuum cleaner station 1 ) can be rotated toward the inside of the housing 100 . Meanwhile, when the door arm 620 pushes the door 610 , the door 610 may rotate toward the outside of the cleaner station 1 .

The door motor 630 may provide power to rotate the door 610 to the door arm 620 . Specifically, the door motor 630 may rotate the door arm 620 in a forward or reverse direction. Here, the forward direction may mean a direction in which the door arm 620 pulls the door 610 toward the inside of the housing 100 . Also, the reverse direction may mean a direction in which the door arm 620 pushes the door 610 toward the outside of the housing 100 .

The door arm 620 is coupled to the door 610 to open and close the door 610 , and serves to connect the door 610 and the door motor 630 . The door arm 620 may open and close the door 610 using power generated from the door motor 630 .

For example, the door arm 620 may include a first door arm 621 and a second door arm 622 . One end of the first door arm 621 may be coupled to the door motor 630 . The first door arm 621 may be rotated by the power of the door motor 630 . The other end of the first door arm 621 may be rotatably coupled to the second door arm 622 . The first door arm 621 may transmit the force transmitted from the door motor 630 to the second door arm 622 . One end of the second door arm 622 may be coupled to the first door arm 621 . The other end of the second door arm 622 may be coupled to the door 610 . The second door arm 622 may push or pull the door 610 .

Hereinafter, an arrangement of the bypass hole 710 formed in the suction pipe 700 and a specific structure for removing residual dust, which is a problem of the present invention, will be described with reference to FIGS. 4 and 6 .

The cleaner station 1 may further include a suction pipe 700 .

First, referring to FIG. 6 , the suction pipe 700 is accommodated in the housing 100 and disposed in the vertical direction, and air containing the dust escaping from the dust container 2600 of the cleaner 2 can flow. It may be provided to provide a space (S1). That is, when the cleaner 2 is coupled to the cleaner station 1 , the dust container 2600 may be disposed at the open upper end of the suction pipe 700 . At this time, since the open lower end of the suction tube 700 is coupled to the dust storage module 300 , when the discharge cover 2620 is separated from the dust container body 2610 , the dust inside the dust container body 2610 is removed from the suction tube 700 . ) through, the dust may be collected by the storage module 300 .

Also, the open upper end of the suction pipe 700 may be defined as a dust passage hole 113a. As described above, the dust passage hole 113a may serve as a main hole for sucking dust from the dust container 2600 into the housing 100 .

A bypass hole 710 may be provided in the suction pipe 700 to remove residual dust. At this time, referring to FIG. 4 , the bypass hole 710 has a push protrusion 511 on the suction pipe 700 in a direction in which the push protrusion 511 presses the coupling lever 2630 coupled to the dust container body 2610 with the push protrusion 511 and It is provided at a position facing, and may be provided in a form penetrating the inside and the outside of the suction pipe 700 . The bypass hole 710 may be provided, for example, in the form of a horizontal long hole. More specifically, the bypass hole 710 may be formed through the suction pipe 700 at the same level as the flat surface 112a on which the protrusion support 512 linearly reciprocates.

The bypass hole 710 may be formed below the dust passage hole 113a. In addition, the bypass hole 710 may be formed to have a cross-sectional area smaller than that of the dust passage hole 113a.

With this configuration, when the dust collecting motor 200 generates a suction force while the dust passage hole 113a is closed, a strong suction force concentrated on a small cross-sectional area can be applied to the bypass hole 710, and effectively the residual dust can be removed.

In addition, with this configuration, when the discharge cover 2620 of the dust container 2600 is opened, the residual dust that has fallen and accumulated in the vicinity of the push protrusion 511 inside the cleaner station 1 is affected by the suction force of the dust collecting motor 200 . may be sucked into the suction pipe 700 through the bypass hole 710 by the That is, if the path sucked into the suction pipe 700 through the dust bin 2600 and the dust passage hole 113a is referred to as the main suction path, the residual dust separated from the dust bin 2600 is near the push protrusion 511 (second coupling). A path sucked from the portion 112 (which may be referred to as the vicinity of the portion 112 ) through the bypass hole 710 to the suction pipe 700 may be referred to as a bypass suction path. The cleaner station 1 according to the embodiment of the present invention can remove dust, which is in danger of being deposited in the space near the push protrusion, through the bypass suction path inside the cleaner station, so that the inside of the cleaner station is not contaminated. It has the effect of reducing the risk and enabling hygienic management of the vacuum cleaner station.

Hereinafter, driving of the dust collecting motor 200 for removing residual dust through the bypass suction path will be described.

After the vacuum cleaner 2 is coupled to the coupling unit 110 and the door unit 600 opens the door 610 , the cover opening unit 500 opens the discharge cover 2620 so that the inside of the dust container body 2610 and When the suction pipe 700 communicates with each other, the dust collecting motor 200 may be driven for the first time t1 . At this time, the air containing dust passes through the main suction path and the bypass suction path to flow into the inner space S1 of the suction pipe 700 , and the dust bag 310 coupled to the lower end of the suction pipe 700 . dust may be collected.

When the dust collecting motor 200 stops driving after the first time t1 has elapsed, the door unit 600 may close the door 610 . When the door arm 620 pushes the door 610 in the direction to close the door 610 , the discharge cover 2620 may also move together with the door 610 in the direction to close the dust container 2600 . Accordingly, the discharge cover 2620 is coupled to the dust container body 2610 again, and the door 610 also closes the dust passage hole 113a.

After the door 610 is closed by the door unit 600 and the dust container 2600 is still coupled to the coupling unit 110 , the dust collecting motor 200 is re-driven for a second time t2 to increase the suction power. can cause Here, since the main suction path is closed, the air containing dust flows into the internal space S1 of the suction pipe 700 through only the bypass suction path. At this time, if the dust collecting motor 200 generates the same suction force, the suction force of the dust collecting motor 200 is larger than when the dust collecting motor 200 was driven in the state in which the door 610 was opened earlier toward the bypass suction path. can be focused

The concentration of the suction force of the dust collecting motor 200 on the bypass suction path means that the suction force acting on the residual dust increases. That is, the dust collecting motor 200 is configured to re-drive in a state in which the discharge cover 2620 and the door 610 are closed, thereby increasing the removal efficiency of residual dust.

In addition, when dust is sucked in by the dust collection motor 200 in a state in which the discharge cover 2620 and the door 610 are open, to the inside of the door 610 (the opposite side of the side facing the discharge cover 2620) Also, dust can fly and stick, and the dust can also be removed by configuring the dust collecting motor 200 to re-drive in the closed state of the door 610 .

Meanwhile, the first time t1 and the second time t2 may be preset in a controller (not shown) of the cleaner station 1 . In this case, the first time t1 for sucking more dust may be set to be longer than or equal to the second time t2 for sucking the remaining dust. The control unit may be accommodated in the housing 100 and may be provided to control driving, stopping, and suction force of the dust collecting motor 200 .

7 is a view looking down at the coupling part 110 from the top, and FIG. 8 is a cross-sectional view of a state in which the cleaner 2 is coupled to the coupling part 110 .

7 and 8, when the direction in which the protrusion support 512 linearly reciprocates is referred to as a first direction, and a direction perpendicular to the first direction is referred to as a second direction, the The size D1 in the second direction may be smaller than the size D2 in the second direction of the flat surface 112a. In other words, from each end of the protrusion support 512 disposed in the second direction to the vertical wall 112b of the second coupling portion 112 may be spaced apart by a predetermined distance.

Foreign substances that have flowed into the second coupling part 112 of the cleaner station 1 show a random form of deposition, and most of them can be removed by the bypass hole 710 formed in the suction pipe 700 . However, when the size D1 in the second direction of the protrusion support 512 and the size D2 in the second direction of the flat surface 112a of the second coupling part 112 are approximately the same, that is, the protrusion support 512. When each end disposed in the second direction of the second coupling portion 112 is in contact with the vertical wall 112b or is configured to be disposed too close, there is a possibility that the deposited foreign material cannot escape into the bypass hole 710 this will get bigger

At this time, in particular, when hard and small foreign substances such as sand grains are deposited in a small gap between the end of the protrusion support 512 and the vertical wall 112b, resistance to linear reciprocation may occur, and the protrusion support 512 may cause foreign substances. It can make a rattling noise when rubbing against them. To solve this problem, the cleaner station 1 according to the embodiment of the present invention may be configured to be spaced apart by a predetermined distance between the end of the protrusion support 512 and the vertical wall 112b. Here, when the discharge cover 2620 is opened by the predetermined distance, it falls by gravity and flows out into the gap between the dust container body 2610 and the coupling part 110 to flow into the second coupling part 112 . It may be selected in consideration of the size of the possible foreign material. (See FIG. 8)

Through such a configuration, it is possible to solve the problems described above (deposition of foreign matter, generation of resistance to linear reciprocation, generation of noise, etc.).

Meanwhile, referring again to FIG. 7 , the moving axis L1 of the linear reciprocating movement direction of the protrusion support 512 may be disposed at the center of the second direction of the flat surface 112a. In other words, the distance from the left end of the protrusion support 512 to the near vertical wall 112b may be the same as the distance from the right end of the protrusion support 512 to the near vertical wall 112b. That is, the second coupling part 112 and the protrusion support 512 may have a symmetrical structure about the movement axis L1 of the protrusion support 512 . Through this configuration, the left and right separation distances between the protrusion support 512 and the vertical wall 112b about the movement axis L1 of the protrusion support 512 can be set to the same minimum distance, and the vacuum cleaner station There is an advantage that the interior space design of (1) is possible.

Hereinafter, the structure of the coupling lever 2630 of the cleaner 2 will be described in detail.

9 is a perspective view of the coupling lever 2630 of the cleaner 2, FIG. 10 is a perspective view of the coupling lever 2630 of FIG. 9 viewed from another direction, and FIG. 11 is a side view of the coupling lever 2630 of FIG. , FIG. 12 is a perspective view illustrating the relationship between the direction in which the lever inclined portion 2632 of the coupling lever 2630 is formed and the moving direction A of the push protrusion 511 .

9 to 12 , the coupling lever 2630 may include a lever body 2631 , a lever inclined portion 2632 , a lever side wall 2633 , a lever pressing portion 2634 , and a hook pressing portion 2635 . can

The lever body 2631 may constitute a part of the outer shape of the coupling lever 2630 . The lever body 2631 may be formed to extend along the length direction of the dust container body 2610 . In this case, the lever body 2631 may be bent by a predetermined length from both ends in the direction perpendicular to the extending direction in the center direction of the dust container body 2610 to form an inner inner space of the coupling lever 2630 . In addition, the lever inclined portion 2632 may be connected to one end in the direction in which the lever body 2631 is extended.

The lever inclined portion 2632 may be connected to the lever body 2631 at one end from which the lever body 2631 is extended and formed to extend from the lever body 2631 .

In this case, the lever inclined portion 2632 may be provided with a dust discharge groove 2632a in which the lever inclined portion 2632 is recessed. Since the dust discharge groove 2632a is provided in the coupling lever 2630 , the residual dust flowing into the coupling lever 2630 can pass through the dust discharge groove 2632a by the suction operation of the dust collecting motor 200 and the suction pipe It may be introduced into 700 and removed.

The lever inclined portion 2632 may be inclined toward the center of the dust container body 2610 based on a state in which the coupling lever 2630 is coupled to the dust container body 2610 . In other words, the lever inclined portion 2632 may be formed to extend from the lever body 2631 and inclined upward by a predetermined angle θ with respect to the moving direction A of the coupling lever 2630 . The lever inclined portion 2632 may be disposed at an angle with respect to the door 610 when the cleaner 2 is coupled to the coupling portion 110 . In other words, the lever inclined portion 2632 may be disposed to face the bypass hole 710 when the cleaner 2 is coupled to the coupling portion 110 . With this configuration, the dust discharge groove 2632a through which the residual dust should be discharged is not blocked by the door 610, and the residual dust can be smoothly removed through the dust discharge groove 2632a to the bypass hole 710. (refer to FIGS. 11 and 12)

The lever side wall 2633 is coupled to the lever body 2631 and the lever pressing part 2632 . One or more sidewall support ribs 2637 disposed toward the inside of the coupling lever 2630 may be coupled to each of the lever sidewalls 2633 .

The lever pressing part 2634 may be coupled to the other end of the lever body 2631 . In this case, the other end of the lever body 2631 may mean a direction opposite to the direction in which the lever inclined portion 2632 is disposed. The lever pressing part 2634 may be formed to extend from the other end of the lever body 2631 in a direction perpendicular to the direction in which the lever body 2631 is extended. The lever pressing unit 2634 is a configuration in which an external force is applied by the user, and when an external force is applied to the lever pressing unit 2634 , the coupling lever 2630 moves in the longitudinal direction of the dust container 2600 to close the discharge cover 2620 . will be open

A lever hole 2634a formed to pass through the lever pressing part 2634 may be provided in the lever pressing part 2634 . The lever hole 2634a may be provided in the form of a long hole penetrating long in the direction in which the lever sidewall 2633 is disposed. Also, the lever hole 2634a and the dust discharge groove 2632a may be disposed to face each other.

When the dust collecting motor 200 generates a suction force by the lever hole 2634a and the dust discharge groove 2632a disposed to face each other, the dust discharge groove ( 2632a), an airflow communicating to the bypass hole 710 may be formed, and since the airflow is not blocked by the lever pressing unit 2634 during the suction operation of the dust collecting motor 200, the suction effect of the residual dust will be further improved. will be able

The hook pressing part 2635 may be coupled to the lever pressing part 2634 . One side of the lever pressing part 2634 may be coupled to the lever body 2631 , and the other side of the lever pressing part 2634 may be coupled to the hook pressing part 2635 . In this case, the hook pressing part 2635 may be formed to extend in the same direction as the lever body 2631 . The hook pressing unit 2635 may press the coupling hook 2660 of the discharge cover 2620 to cause elastic deformation in the coupling hook 2660 . In other words, when an external force is applied to the lever pressing unit 2634 by the user, the hook pressing unit 2635 may press the coupling hook 2660 and the discharge cover 2620 may be opened. (See FIG. 12 )

13 is a schematic diagram of a suction path of residual dust through the dust discharge groove 2632a and the bypass hole 710 of the coupling lever 2630 .

12 and 13 , the residual dust flowing into the second coupling part 112 during the process of opening the discharge cover 2620 or the process of dust being sucked into the vacuum cleaner station 1 is the second coupling part ( 112 may be sucked into the suction pipe 700 through the bypass hole 710 . In addition, when the discharge cover 2620 is opened or the dust is sucked into the cleaner station 1, it flows into the inside of the coupling lever 2630 (the space between the coupling lever 2630 and the dust container body 2610). Residual dust may be sucked into the suction pipe 700 from the dust discharge groove 2632a through the bypass hole 710 .

Next, a method for removing residual dust using the cleaner system 1000 according to an embodiment of the present invention will be described with reference to FIG. 14 .

14 is a flowchart of a method for removing residual dust using the cleaner system 1000 according to an embodiment of the present invention.

First, when it is confirmed whether the cleaner 2 is coupled to the coupling part 110 ( S100 ), in the door opening step, the door 610 provided in the cleaner station 1 is opened to communicate the outside and the inside of the cleaner station 1 . (S200) In this case, the opening of the door 610 may be performed by the door unit 600 of the cleaner station 1 described above.

On the other hand, a coupling sensor (not shown) may be disposed on the coupling part 110 to check whether the cleaner 2 is coupled to the coupling part 110 . The coupling sensor may be a contact sensor, such as a micro switch, or a non-contact sensor, such as an infrared sensor.

Next, in the step of opening the discharge cover 2620 , the discharge cover 2620 for opening and closing the dust container 2600 is opened ( S300 ). At this time, the opening of the discharge cover 2620 is the cover of the cleaner station 1 described above. It may be performed by the opening unit 500 .

When both the door 610 and the discharge cover 2620 are opened and the suction pipe 700 communicates with the inside of the dust container body 2610, it goes to the dust collection stage and the dust collection motor 200 is driven to the inside of the cleaner station 1 Dust is sucked in. (S400) The dust collecting motor 200 may be driven for a first predetermined time t1. At this time, the air containing dust flows through the main suction path and the bypass suction path to the suction pipe 700 , and dust may be collected in the dust bag 310 .

When the dust collecting motor 200 stops and stops driving after the first time t1 has elapsed (S500), the door unit 600 may close the door 610 together with the discharge cover 2620 in the door closing step. (S600) When the door arm 620 of the door unit 600 pushes the door 610 in the direction to close the door 610, the discharge cover 2620 also moves in the direction to close the dust bin 2600. The discharge cover 2620 is coupled to the dust container body 2610 again, and the door 610 also closes the dust passage hole 113a.

Meanwhile, after the door closing step, a residual dust removal step of removing residual dust existing around the dust container 2600 is performed (S700).

At this time, in the step of removing the residual dust, the dust collecting motor 200 is re-driven for a predetermined time while the cleaner 2 is coupled to the cleaner station 1 , so that the residual dust is transferred to the inside of the cleaner station 1 . It is an inhalation process. More specifically, after the door 610 is closed by the door unit 600 , in a state in which the dust container 2600 is coupled to the coupling unit 110 , the dust collecting motor 200 is re-driven for a second time t2 . This can generate suction power. At this time, since the main suction path is closed, the air containing dust passes only through the bypass suction path and flows into the suction pipe 700 while the dust collecting motor 200 is re-driven. Accordingly, when the dust collecting motor 200 generates the same suction force, the suction force may be more concentrated in the bypass suction path. That is, since the dust collecting motor 200 is configured to re-drive in a state in which the discharge cover 2620 and the door 610 are closed, the suction force provided to the residual dust increases, thereby increasing the removal efficiency of the residual dust.

On the other hand, the bypass suction path may be a path in which the residual dust flowing into the second coupling part 112 is sucked into the suction pipe 700 through the bypass hole 710 , or into the inside of the coupling lever 2630 . It may also be a path through which the flowed residual dust is sucked into the suction pipe 700 through the dust discharge groove 2632a and the bypass hole 710 .

In addition, the first time t1 and the second time t2 may be a predetermined time preset in the controller (not shown) of the cleaner station 1, and the first time ( t1) may be set to be longer than or equal to the second time t2 for inhaling the residual dust. The control unit may be accommodated in the housing 100 and may control driving, stopping, and suction force of the dust collecting motor 200 .

Finally, when the second time t2 has elapsed, the dust collecting motor 200 is stopped ( S800 ) and all operations of the cleaner station 1 are terminated.

As described above, according to the present invention, residual dust accumulated in the vicinity of the push protrusion inside the cleaner station can be effectively sucked through the bypass hole provided to penetrate the outside and the inside of the suction pipe.

Further, according to the present invention, residual dust accumulated inside the coupling lever outside the dust box of the cleaner can be effectively removed through the dust discharge groove formed in the coupling lever of the cleaner.

In addition, according to the present invention, the suction power for sucking the residual dust is transferred to the bypass hole and the above through the residual dust removal step of re-driving the dust collecting motor for a predetermined time after the suction of the dust inside the dust bin is finished and the discharge cover is closed. Since it can be concentrated into the dust outlet groove, residual dust can be removed more effectively.

In the foregoing, specific embodiments of the present invention have been described and illustrated, but the present invention is not limited to the described embodiments, and those of ordinary skill in the art may make various changes to other specific embodiments without departing from the spirit and scope of the present invention. It will be appreciated that modifications and variations are possible. Accordingly, the scope of the present invention should not be defined by the described embodiments, but should be defined by the technical idea described in the claims.

1000: cleaner system
1: Cleaner Station
100: housing 100a: first outer wall surface
110: coupling part 111: first coupling part
111a: curved portion 111b: protruding jaw
112: second coupling portion 112a: flat surface
122aa: projection insertion hole 112b: vertical wall
113: third coupling part 113a: dust passage hole
110b: second outer wall surface 110c: third outer wall surface
110d: fourth outer wall surface 110e: ground support
200: dust collection motor 300: dust storage module
310: dust bag 320: dust storage module housing
500: cover opening unit 510: push unit
511: push projection 512: projection support
513: projection neck 514: gear engagement block
520: cover opening gear 521: first cover opening gear
522: second cover opening gear 600: door unit
605: door hinge 610: door
620: door arm 621: first door arm
622: second door arm 630: door motor
700: suction pipe 610: bypass hole
2: vacuum cleaner
2000: vacuum cleaner body 2100: suction unit
2200: dust separator 2300: suction motor
2400: handle 2500: battery housing
2600: dust bin 2610: dust bin body
2620: exhaust cover 2630: coupling lever
2631: lever body 2632: lever inclined portion
2632a: dust vent groove 2633: lever side wall
2634: lever pressing part 2634a: lever hole
2635: hook pressing part 2636: side wall support rib
2640: dustbin hinge 2650: body jaw

Claims (6)

A main body including a suction unit having a suction passage through which air flows, a dust separation unit including a cyclone unit for separating dust, and a suction motor generating suction force for sucking air along the suction unit, and the dust separation a cleaner including a dust bin for storing dust separated through the unit; and
A coupling part to which the dust container is coupled; a dust storage module for collecting dust inside the dust container; a dust collecting motor generating a suction force for sucking dust inside the dust container into the dust storage module; and the dust storage module and the dust collecting motor Including; and a cleaner station including a housing having therein along the longitudinal direction.
The coupling part,
coupled to a part of the outer circumferential surface of the dust container,
The vacuum cleaner station,
a suction pipe disposed in the vertical direction inside the housing, one end connected to the coupling part, and a flow path through which dust is formed therein;
The flow path of the suction pipe,
The cleaner system according to claim 1, wherein the cleaner is disposed to face an outer circumferential surface of the dust container in a state in which the cleaner is coupled to the cleaner station.
According to claim 1,
The vacuum cleaner system, characterized in that the flow direction of the dust flowing into the flow path of the suction pipe from the inside of the dust container is changed at least once in the flow path of the suction pipe.
According to claim 1,
In a state in which the cleaner is coupled to the cleaner station, a longitudinal axis of the dust container intersects a longitudinal axis of the housing.
4. The method of claim 3,
A direction crossing the longitudinal axis of the dust container is a direction perpendicular to the longitudinal axis of the housing.
According to claim 1,
In a state in which the cleaner is coupled to the cleaner station, a longitudinal axis of the suction unit is disposed parallel to a longitudinal axis of the housing.
According to claim 1,
In a state in which the cleaner is coupled to the cleaner station, a longitudinal axis of the dust container is disposed parallel to the ground.

Images