KR20070103248A - Cleaner system - Google Patents

Abstract

A cleaner system is provided to allow a user to use a vacuum cleaner by clamping a suction tube to a main body and to use the vacuum cleaner as a docking station by clamping an interface to the main body. A cleaner system comprises a vacuum cleaner, a robot cleaner(100), an interface(300). The vacuum cleaner includes a suction body, a main body(30), and suction tubes. The suction body sucks dust. The main body has a suction unit(130) supplies suction force to the suction body. The removable suction tube is clamped to the main body to connect the suction body with the main body. The robot cleaner cleans the floor automatically. The interface is mounted to the main body to uses the main body as a docking station(200). The interface includes a connection unit(310) and a control unit(350). The connection unit provides a discharge path(340) discharging dust in the robot cleaner to the main body when the robot cleaner docks with the main body. The control unit operates the suction unit.

Description

Cleaner System {CLEANER SYSTEM}

1 is a view showing a case where the vacuum cleaner system is used as a vacuum cleaner.

2 is a view showing the robot cleaner when the cleaner system is used as the robot cleaner system.

3 shows a docking station when a cleaner system is used as the robot cleaner system.

4 is a view showing a robot cleaner docked to a docking station when the cleaner system is used as the robot cleaner system.

** Description of the symbols for the main parts of the drawings **

30 Main Unit 40: First Suction Unit

50: first dust collection unit 100: robot cleaner

115: outlet 140: switchgear

145: limiter 200: docking station

300: interface 310: connecting device

312: extension pipe 320: coupling pipe

322: protrusion 330: lifting device

340: discharge passage

The present invention relates to a cleaner system, and more particularly, to a robot cleaner system including an interface for enabling the body of the vacuum cleaner to be used as a docking station to which the robot cleaner is docked.

A vacuum cleaner is a device that cleans dust by removing dust in the room, and a vacuum cleaner that removes dust by using suction power of a suction unit is generally used. Recently, the vacuum cleaner has an automatic driving function and moves itself without a user's operation. Robot cleaners are being developed to remove foreign substances such as dust from the floor.

Such a robot cleaner is located at a specific place in the room and forms a robot cleaner system together with a station (hereinafter referred to as a docking station) that is responsible for charging the robot cleaner or emptying dust stored in the robot cleaner.

One example of such a robot vacuum cleaner system is disclosed in US 2005/0150519. The disclosed robot cleaner system includes a docking station having a robot cleaner and a suction unit for sucking dust.

The lower surface of the robot cleaner is provided with a suction port for sucking dust, and the side of the robot cleaner is provided with a connection terminal for connecting to the docking station for charging the rechargeable battery. An inclined surface is formed in the lower portion of the docking station so that the robot cleaner can be raised, and an inlet for sucking dust from the robot cleaner is formed in the upper portion of the inclined surface. Moreover, the connection terminal which connects with the connection terminal of a robot vacuum cleaner is formed in the side of a docking station.

However, the conventional robot cleaner system as described above has the following problems.

The robot cleaner could not clean the corner of the room. Therefore, in order to clean the corners of the room, the user had to purchase a separate vacuum cleaner in addition to the robot vacuum cleaner system, which was expensive.

In addition, since the suction port is formed on the inclined surface of the docking station, the robot cleaner discharges dust through the inlet in a state in which the robot cleaner is raised along the inclined surface of the docking station, and the robot cleaner positioned on the inclined surface is continuously forced downward in the inclined surface. .

As described above, while the robot cleaner continues to receive force in the downward direction of the inclined surface, there is no device for reliably maintaining the docking state of the robot cleaner and the docking station. Therefore, when the suction port formed on the inclined surface of the docking station and the suction port of the robot cleaner are not exactly positioned, the dust is discharged from the robot cleaner and the dust discharged from the robot cleaner is discharged into the indoor space rather than being sucked into the docking station, thereby There was a problem spotted.

The present invention is to solve the above problems, an object of the present invention can be used as a part of the docking station docked with a vacuum cleaner that the user directly manipulates and a robot cleaner that automatically cleans without the user's operation. So as to provide one cleaner system.

In addition, another object of the present invention is to increase the fastening force of the robot cleaner and the docking station, to provide a cleaner system that does not worry that dust is leaked into the indoor space when the dust is discharged from the robot cleaner to the docking station.

      The cleaner system according to the present invention for achieving the above object is a suction body for sucking dust, a main body provided with a suction unit for generating a suction force to the suction body, and detachably coupled to the main body and the suction body and the main body A vacuum cleaner having a connecting tube for connecting, a robot cleaner for automatically cleaning dust on the floor, and a detachable coupling to the main body so that the main body can be used as a docking station of the robot vacuum cleaner. And an interface including a connecting device for forming a discharge passage through which the dust is discharged from the robot cleaner to the main body when docked to the main body, and a control unit for operating the suction unit.

In addition, the connecting device is characterized in that it comprises an extension tube coupled to the extension and the extension tube coupled to the main body and coupled to the outlet of the robot cleaner when the robot cleaner is docked to the main body.

In addition, the coupling pipe is formed with a protrusion protruding in the radial direction from the outer peripheral surface of the coupling pipe, the discharge port of the robot cleaner is limited to limit the movement of the protrusion when the coupling pipe is coupled to the outlet of the robot cleaner It is characterized by the provision.

The limiting part may include a groove formed in the radial direction of the outlet of the robot cleaner, an elastic member inserted into the groove, and a ball coupled to one end of the elastic member to be elastically supported.

In addition, the coupling pipe is lifted by a lifting device that operates in response to the signal of the controller when the robot cleaner is docked to the main body.

In addition, the elevating device is characterized in that it comprises a rack formed in the coupling pipe and the drive device operating in accordance with the signal of the control unit and the pinion coupled to the rack and driven by the drive device.

Hereinafter, a cleaner system according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 illustrates a case where a cleaner system is used as a vacuum cleaner that a user manipulates and cleans.

The vacuum cleaner collects dust suctioned by the suction unit 10 and the suction unit 10 and the suction unit 10 for generating suction force in the suction unit 10 and the inside of the suction body 10 for sucking dust or foreign substances on the floor. Connecting the suction body 10 and the main body 30 so that the suction force generated in the main body 30 and the first suction unit 40 having the first dust collecting unit 50 is transmitted to the suction body 10 A suction pipe 20 is provided.

The suction pipe 20 is composed of the first suction pipe 20a and the second suction pipe 20b, and a user manually suctions the suction force of the first suction unit 40 between the first suction pipe 20a and the second suction pipe 20b. The handle 21 is provided with an operation switch 22 to operate the. The first suction pipe 20a is formed of an elastic corrugated pipe, one end of which is connected to the main body 30 and the other end of which is connected to the handle 21. One end of the second suction pipe 20b is connected to the suction body 10 and the other end is connected to the handle 21 so that the user can freely clean the standing state.

The insertion hole 31 is formed in the main body 30 so that the first suction pipe 20a can be inserted, and the terminal 32 is provided in the insertion hole 31. The terminal 32 provided in the insertion hole 31 is provided in the first suction pipe 20a and connected to the terminal 23 that is circuitly connected to the operation switch 22.

Therefore, when the user operates the operation switch 22, the microcomputer (not shown) provided in the main body 30 receives a signal from the operation switch 22 to operate the first suction unit 40.

2 and 3 illustrate a case where the cleaner system is used as a robot cleaner system that does not require user manipulation.

The robot cleaner system has an automatic driving function so that a certain amount of dust is accumulated or charged in the robot cleaner 100 and the robot cleaner 100 to remove foreign substances such as dust from the floor while moving by themselves without the user manipulating them one by one. Docking station 200 that returns when it is necessary to charge 150.

In the robot cleaner system, the vacuum cleaner body 30 described with reference to FIG. 1 forms part of the docking station 200.

As shown in FIG. 2, the robot cleaner 100 has a robot main body 110 having a suction port 111 for sucking dust and a second dust collector installed inside the robot main body 110 to store the sucked dust. The second suction unit 130 communicates with the unit 120 and the second dust collecting unit 120 and generates a suction force for sucking dust.

A filter 131 is installed between the second dust collecting unit 120 and the second suction unit 130 to prevent dust from flowing into the second suction unit 130. Although not shown in the drawing, the second suction unit 130 includes a motor for generating power and a blowing fan for generating a blowing force by receiving the power of the motor, and the robot body 110 inside the second dust collecting unit 120. Dust sensor is installed to detect the amount of accumulated dust.

The lower part of the robot body 110 is provided with a pair of electric wheels 112 to move the robot cleaner 100, the pair of electric wheels 112 is selectively by a drive motor (not shown) to rotate each The robot cleaner 100 is driven to allow linear motion and rotational motion. On the outside of the robot body 110, an obstacle sensor 113 such as an infrared sensor or an ultrasonic sensor is installed to defeat an obstacle.

The robot cleaner 100 receives the air sucked by the suction port 111 and the second suction unit 130 formed below the robot main body 110 to suck dust from the bottom surface of the cleaning area of the robot main body 110. The discharge port (not shown) for discharging to the outside and the robot cleaner 100 has a discharge port 115 for discharging dust to the docking station 200 when docked in the docking station 200.

Outlet 115 is formed to communicate from the second dust collecting unit 120, the outlet 115 is an opening and closing device for opening and closing the outlet 115 only when the robot cleaner 100 is docked to the docking station (200) ( 140 is provided. When the robot cleaner 100 automatically cleans the opening and closing device 140, the outlet 115 is closed to prevent the suction force of the second suction unit 120 from leaking to the outlet 115 and the robot cleaner. When the 100 is docked in the docking station 200 to remove dust in the second dust collecting unit 120, the dust is opened to allow the dust inside the second dust collecting unit 120 to move to the docking station 200.

In addition, the robot cleaner 100 has a charging battery 150 for supplying power required for its operation. The charging battery 150 is connected to the connection terminal 151 protruding to the outside of the robot body 100 to be charged when the robot cleaner 100 is docked to the docking station 200.

Meanwhile, while the robot cleaner 100 autonomously moves the area to be cleaned and automatically cleans it, when a certain amount of dust accumulates inside the second dust collecting unit 120 or when the charging battery 150 needs to be charged, the robot cleaner 100 returns to docking. Is provided with a docking station 200.

As shown in FIG. 3, the docking station 200 is detachably coupled to the main body 30 and the main body 30, and has an interface 300 that links the robot cleaner 100 and the main body 30.

The main body 30 uses the main body of the vacuum cleaner described above as it is, and is installed inside the main body 30 so as to generate a suction force when suctioning the dust of the second dust collecting unit 120 and the first suction unit 40. It has a first dust collecting unit 50 for collecting dust sucked from the second dust collecting unit 120. In addition, the main body 30 is provided with a charging device 35 for charging the charging battery 150 of the robot cleaner 100. One side of the charging device 35 is provided with a connection terminal 36 for connecting the connection terminal 151 of the robot cleaner 100 when the robot cleaner 100 is docked, the charging battery 35 on the other side of the charging device 35 The connection detecting device 37 for detecting that the connection terminal 151 of the 150 and the connection terminal 36 of the charging device 35 is connected is installed.

The interface 300 maintains the docked state when the robot cleaner 100 is docked to the docking station 200 and at the same time, discharges the discharge passage 340 from which the dust is discharged from the robot cleaner 100 to the docking station 200. The control unit 350 operates the first suction unit 40 when the connection device 310 and the robot cleaner 100 to be formed are docked to the docking station 200, and the coupling pipe 320 to be described later moves up and down. It is provided.

The connection device 310 is composed of a coupling part 311 inserted into the insertion hole 31 of the main body 30 and an extension tube 312 extended to suck dust collected in the robot cleaner 100.

The coupling part 311 is provided with a terminal 311a connected to the terminal 32 provided in the insertion hole 31 of the main body 30 and connected to the control unit 350 in a circuit.

The extension tube 312 is composed of a horizontal extension tube 312a extending horizontally again and a vertical extension tube 312b extending downward. The coupling pipe 320 is installed in the vertical extension pipe 312b to move up and down, and the coupling pipe 320 is inserted into the discharge port 115 of the robot cleaner 100 at the end of the coupling pipe 320 is connected. It is prepared. In addition, the elevating device 330 for elevating the coupling pipe 320 up and down is provided inside the vertical extension pipe 312b. In this embodiment, the drive unit (not shown) and the rack 331 which operate according to the signal of the rack 331 and the control unit 350 formed in the coupling pipe 320 by the elevating device 330 and the drive unit by The pinion 332 is driven, but is not necessarily limited thereto, and any structure may be used as long as the coupling pipe 320 is lifted up and down.

On the other hand, when the robot cleaner 100 is docked to the docking station 200, when the coupling pipe 320 is lowered and coupled to the outlet 115 of the robot cleaner 100, the robot cleaner 100 and the docking station 200 In order to increase the coupling force of the coupling pipe 320 is formed with a protrusion 322 protruding in the radial direction from the outer peripheral surface, the outlet 115 of the robot cleaner 100 is limited to limit the movement of the protrusion 322 Part 145 is formed.

The restricting part 145 is coupled to one end of the elastic member 147 and the elastic member 147 inserted into the groove 146 and the groove 146 formed in the radial direction of the outlet 140 and the ball 148 to be elastically supported. It is provided.

Hereinafter, the operation of the robot cleaner system will be described with reference to FIG. 4.

When the cleaning starts, the robot cleaner 100 removes foreign substances in the area to be cleaned while moving autonomously. At this time, the opening and closing device 140 of the robot cleaner 100 closes the outlet 115 to prevent the suction force by the second suction unit 130 from leaking to the outlet 115. After a certain period of time, when a certain amount of dust is accumulated in the first dust collector 120, the robot cleaner 100 stops cleaning and returns to the docking station 200 to remove the dust. When the connection detecting apparatus 260 detects that the robot cleaner 100 returns to a predetermined position and the connection terminal 151 of the robot cleaner 100 and the connection terminal 251 of the docking station 200 are connected to each other, The opening and closing device 140 of the robot cleaner 100 is opened.

On the other hand, the control unit 350 of the interface 300 operates the driving device (not shown) to lower the coupling pipe 320 to the lower side.

When the coupling pipe 320 moves downward in the open / close device 140, the protrusion 322 of the coupling pipe 320 is pushed in the direction in which the ball 148 is inserted into the groove 146.

When the ball 148 is pushed in the direction in which the groove 146 is inserted, the elastic member 147 is compressed while receiving elasticity, and the coupling pipe 320 continues to move downward so that the protrusion 322 is lower than the ball 148. When placed in the ball 148 is returned to its original state by receiving the elastic restoring force of the elastic member 147. In this way, when the coupling pipe 320 is inserted into the outlet 115 of the robot cleaner 100 and coupled, the protrusion 322 is caught by the ball 148 so that the coupling pipe 320 does not fall out of the outlet 115 well. The fastening force between the robot cleaner 100 and the docking station 200 is increased.

In addition, when the coupling pipe 320 is inserted into the discharge port 115, the discharge port 115 of the robot cleaner 100 and the insertion hole 31 of the main body 30 is connected by the connecting device 310, the robot cleaner 100 The discharge passage 340 is discharged inside the dust is formed. As described above, when the discharge passage 340 is formed, the controller 350 operates the first suction unit 40, and when the first suction unit 40 operates, dust inside the second dust collecting unit 120 is discharged. The inside of the second dust collecting unit 120 is neatly emptied by being sucked into the first dust collecting unit 40 through the passage 340.

As described above, the user can be used as a vacuum cleaner that the user directly operates by cleaning the suction pipe 20 to the main body 30, the robot cleaner 100 by coupling the interface 300 to the main body 30 May be used as the docking station 200 to which the docking station is docked.

As described in detail above, according to the cleaner system according to the present invention, since the main body of the vacuum cleaner that the user directly manipulates can be used to configure a part of the docking station of the robot cleaner that automatically cleans, the robot cleaner system and the vacuum cleaner This can reduce the cost of having to arrange it separately.

In addition, since the fastening force between the robot cleaner and the docking station can be increased, it is possible to prevent the dust from leaking into the indoor space when the dust is sucked from the robot cleaner to the docking station.

Claims (6)

A vacuum cleaner including a suction body for sucking dust, a main body provided with a suction unit generating suction force in the suction body, and a suction tube detachably coupled to the main body and connecting the suction body and the main body; A robot cleaner that automatically cleans dust on the floor, A connecting device detachably coupled to the main body so that the main body can be used as a docking station of the robot vacuum cleaner, and forming a discharge passage through which the dust is discharged from the robot vacuum cleaner to the main body when the robot vacuum cleaner is docked to the main body; And an interface having a control unit for operating the suction unit. The method of claim 1, The connecting device is a cleaner system, characterized in that it comprises an extension pipe coupled to the extension and the extension pipe and the coupling pipe coupled to the outlet of the robot cleaner when the robot cleaner is docked to the main body. The method of claim 2, The coupling pipe is provided with a protrusion projecting radially from the outer circumferential surface of the coupling pipe, the discharge port of the robot cleaner is provided with a restriction for limiting the movement of the protrusion when the coupling pipe is coupled to the outlet of the robot cleaner Cleaner system, characterized in that. The method of claim 3, wherein The restricting unit includes a groove formed in the radial direction of the outlet of the robot cleaner, an elastic member inserted into the groove, and a ball coupled to and elastically supported at one end of the elastic member. The method of claim 2, The coupling pipe is a vacuum cleaner system, characterized in that the lift by the lifting device which operates in response to the signal of the controller when the robot cleaner is docked to the main body. The method of claim 5, The elevating device includes a rack formed in the coupling pipe and a driving device operating according to a signal from the controller, and a pinion coupled with the rack and driven by the driving device.

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