This application may relate to co-pending, commonly owned U.S. patent application Ser. Nos. 10/753,322, filed Jan. 9, 2004, and 10/887,840, filed Jul. 12, 2004, the subject matter of each of which is incorporated herein by reference.
This application claims benefit under 35 U.S.C. ยง119(a) of Korean Patent Application No. 2005-125664, filed Dec. 19, 2005, the entire contents of which are incorporated herein by reference.
The present invention relates to a vacuum cleaner. More particularly, the present invention relates to a robot vacuum cleaner that adopts a cyclone structure.
Conventional robot cleaners generally comprise a dust suction unit, which includes a suction port and a rotary brush, a suction motor which provides a vacuum source, a sensor unit which includes an obstacle sensor and a distance sensor measuring a traveling distance and location, driving rollers mounted on both sides thereof, a driving motor for driving the driving rollers, a diverting roller mounted on front and rear sides thereof, and a control unit which controls the dust suction unit, the sensor unit and the driving unit.
The dust suction unit of a conventional robot cleaner usually uses a dust bag made of paper or fabric to collect dust therein. The dust bag also serves as a filter. When using a dust bag made of plastic, a predetermined filter is often separately installed to filter air and discharge the filtered air toward the suction motor. However, when the dust bag is full or the dust receptacle is blocked, the suction force drops considerably, accordingly deteriorating cleaning performance.
Also, conventional robot cleaners generally use a rechargeable battery, which supplies limited amounts of electric power, and accordingly uses a small-size suction motor consuming relatively less power to maintain compact size of the robot cleaner. However, such a small-size suction motor has lower suction efficiency than general suction motors.
In order to overcome the limited suction efficiency of the small-size suction motor, a cyclone structure has been widely used, which is superior to the dust bag with regards to the suction efficiency and even recyclable. Exemplary robot cleaners adopting such a cyclone structure are disclosed in British Patent No. 2344778 and Korean Patent No. 333880, the subject matter of each of which is incorporated by reference.
In British Patent No. 2344778, cyclone units having a conical shape are laterally mounted. However, since this structure increases the volume of the cyclone unit, the robot cleaner is bulky and not compact. In the robot cleaner disclosed in Korean Patent No. 333880, a cyclone unit having a cylindrical form is vertically mounted into a cleaner body and is fluidly communicated through a separate suction pipe connected to a suction port. This structure also makes it hard to compactly design the robot cleaner because the dust receptacle connected to a lower part of the cyclone unit increases the height of dust collection unit.
Furthermore, the cyclone structures as disclosed in British Patent No. 2344778 and Korean Patent No. 333880 have a longer dust suction path for generating a rotating air current than the dust bag structure. The long dust suction path causes loss of energy due to friction with the rotating air current, thereby seriously deteriorating the initial suction force.
If a medium-size motor having higher suction efficiency is used, more rechargeable batteries are required to supply more electric power for driving the medium-size motor. However, this increases weight of the robot cleaner. Additionally, when adopting the cyclone structure in a robot cleaner, centroid of the robot cleaner inclines to the upper side as the height of the robot cleaner is increased. If the robot cleaner climbs an obstacle, such as a doorsill, the robot cleaner may fall down and be damaged.
An aspect of the present invention is to solve at least the above problems and/or disadvantages and to provide at least the advantages described below. Accordingly, an aspect of the present invention is to provide a robot cleaner having compact size.
Another aspect of the present invention is to provide a robot cleaner with a high suction force although adopting a cyclone structure.
In order to achieve the above-described aspects of the present invention, there is provided a robot cleaner that has a dust collection unit including a cyclone part generating an ascending rotary air current from the dust-laden air being drawn in through a lower part thereof, separating the dust from the air using a centrifugal force, and discharging the dust-separated air to the lower part through a center part; and a collection part surrounding the cyclone part to receive the dust being centrifugally separated. According to this structure, the height of the robot cleaner can be reduced, thereby providing a compact robot cleaner.
The dust collection unit may overlap, at a lower part thereof, with a discharge path for guiding the air dust-separated by the dust collection unit to a discharge port.
The cyclone part may include an inner canister for discharging therethrough the dust-separated air to a discharge path; an outer canister enclosing the inner canister and forming a boundary between the cyclone part and the collection part; and a bottom wall disposed at the inner and the outer canisters to form a spiral path, wherein the bottom wall isolates one side of a suction path and the discharge path from the spiral path, respectively.
Accordingly, since the rotative force is exerted through the spiral path to the air being drawn in through the suction path, a high average suction force as well as a high initial suction force can be guaranteed. Also, the size of the robot cleaner can be slimed by adopting the cyclone part having the low height.
The dust collection unit may further comprise a cover removably connected to an upper part thereof to open and close the cyclone part and the collection part. The cover may comprise a concave portion disposed on the cover at a position corresponding to the inner canister of the cyclone part and recessed toward the inner canister, to decrease volume of an upper end portion of the inner canister for favorable discharge of the air dust-separated by the cyclone part; and one or more handles mounted in the concave to help withdrawal of the dust collection unit from the cleaner body. The one or more handles may be pivotably mounted by one ends thereof by a fixing projection formed in the concave.
The robot cleaner may further comprise a locking unit for connecting the cover lockably to the dust collection unit. The locking unit may comprise a pivot shaft pivotably connected to one lower side of the cover; a lever connected to one side of the pivot shaft to rotate the pivot shaft; one or more driving hooks connected by one ends thereof to a circumference of the pivot shaft and pivoting by an angle the same as a rotating angle of the pivot shaft; one or more fixing hooks dispose at one side of the dust collection unit and snap-connected with the one or more driving hooks; and a return spring exerting resilience to the pivot shaft so as to resiliently bias the one or more driving hooks toward the corresponding fixing hooks.
According to another aspect of the present invention, there is provided a vacuum cleaner that has dust collection unit with a cyclone part generating an ascending rotary air current from the dust-laden air being drawn in through a lower part thereof, separating the dust from the air using a centrifugal force, and discharging the dust-separated air to the lower part through a center part; and a collection part surrounding the cyclone part to receive the dust being centrifugally separated, and the dust collection unit overlapping at a lower part thereof with a discharge path for guiding the air dust-separated by the dust collection unit to a discharge port.
The above aspect and other features of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawing figures, wherein;
Hereinafter, a robot cleaner according to an embodiment of the present invention will be described in detail with reference to the accompanying drawing figures.
In the following description, same drawing reference numerals are used for the same elements even in different drawings. The matters defined in the description such as a detailed construction and elements are nothing but the ones provided to assist in a comprehensive understanding of the invention. Thus, it is apparent that the present invention can be carried out without those defined matters. Also, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.
Also, description about general component parts of a robot cleaner, for example, a driving unit for automatic traveling, a sensor unit, and a control unit for conducting the driving unit and the sensor unit, will be omitted herein. Instead, the present invention will be described featuring a dust collection unit capable of realizing slim and compact size and guaranteeing a high suction force.
As shown in
As shown in
The dust collecting body 110 includes a cyclone part 116 that accepts dust and air from a lower side thereof through the suction port 21 of the cleaner body 11 and through a suction path P1 (
In addition, the dust collecting body 110 comprises a discharge path P3 (
As shown in
As shown in
According to the embodiment of the present invention by adopting the slim cyclone part 116, a suction force as high as the initial suction force can be maintained even if a small-size suction motor (not shown) is used, thereby improving cleaning performance.
The cover 120 may be removably connected to the upper part of the dust collecting body 110 to open and close the cyclone part 116 and the collection part 117. The cover 120 comprises a substantially hemispheric concave portion 121 recessed toward the inner canister 111. The concave portion 121 guides the dust separated from the air from the spiral path P2, to the collection part 117 disposed around the cyclone part 116. In addition, the concave portion 121 may form the upper end of the inner canister 111, where the air is drawn in, to narrow the open end so that air passing through the spiral path P2 is quickly drawn into the inner canister 111.
As shown in
Preferably when the handles 125a and 125b are seated in the concave portion 121 with the fixing projection 123 they have height less than the depth of the concave portion 121. When the dust collection unit 100 is mounted in the cleaner body 11 and the main cover 15 (
As shown in
For resilient snap-connection of the first and the second driving hooks 135a and 135b with the first and the second fixing hooks 139a and 139b, respectively, the locking unit 130 may include a return spring 137 at one side of the pivot shaft 133. As shown in
The operations of the locking unit 130 will be described with reference to
Referring to
Accordingly, the first driving hook 135a is pivoted together with the pivot shaft 133 in a direction going away from the dust collecting body 110. As a result, the snap-connection between the first driving hook 135a and the first fixing hook 139a is released, thereby releasing the locking unit 130. Then, the cover 120 can be separated from the cleaner body 110 simply by operating the lever 131.
The dust-suction operations of the robot cleaner 10 according to an embodiment of the present invention will now be described hereinafter.
Upon being powered, the robot cleaner 10 travels on the surface being cleaned along a predetermined route, drawing in dust and air through the suction port 21 via a suction motor (not shown), as shown in
The dust-separated air descends back along the inner canister 111, moves along the discharge path P3, and is drawn into a motor chamber 17 through the discharge port 23. The air drawn into the motor chamber 17 is passed through the suction motor (not shown) and discharged to the outside of the cleaner body 11.
According to the embodiment of the present invention as described above, the cyclone part 116, the inner canister 111, and the collection part 117 are arranged breadthwise, and part of the suction path P1 and the discharge path P3 are disposed overlappingly with the cyclone part 116. Therefore, the robot cleaner 10 can be implemented in a slim compact shape.
In addition, since the rotative force is exerted on the air being drawn into the cyclone part 116 through the spiral path P2 formed in the cyclone part 116, a high average suction force as well as a high initial suction force can be guaranteed.
Moreover, the at least one handle 125a and 125b pivotably mounted in the concave portion 121 of the cover 120 facilitates withdrawal of the dust collection unit 100 from the cleaner body 110 without changing the whole contour of the cyclone part 116 or deteriorating the dust separating performance of the cyclone part 116. Accordingly, the dust collection unit 100 can be conveniently mounted and separated with respect to the cleaner body 110, and maintenance of the robot cleaner 10 as well as the dust collection unit 100 is also facilitated. Furthermore, since the cover 120 is lockably connected to the dust collection unit 100, the dust separated is collected in the dust collection unit 100. Therefore, contamination of the environment is prevented, thereby enabling hygienic use of the cleaner.
While the invention has been shown and described with reference to certain embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.
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