There are robotic cleaning vehicles which traverse the bottom of swimming pools and other large liquid containers submerged in the contained liquid. The robotic cleaning vehicle draws in liquid from ports in their bottom and passing the liquid through filters in the body of the vehicle and expels the filtered liquid back into the large container, typically a swimming pool. These vehicles typically travel on wheels which suspend the body of the vehicle above the bottom of the container. In some cases these wheels are mounted on axles and one of the axles is held at angle other than perpendicular to the general direction of movement of the vehicle so that as the vehicle moves forward and back on its wheels it follows a path that covers a significant portion of the container.
A self directed pool cleaning vehicle comprising a body includes a water inlet port and a water outlet port with the inlet port being located on the bottom of the body and containing a filter. A drive mechanism mounted to the body propels the vehicle in two generally opposed directions. A first axle and a second axle, with each axle carrying two wheels at either end, support the body and control its direction of movement in response to the drive mechanism. The axles are mounted to the body such that they can be generally perpendicular to the directions in which the drive mechanism propels the vehicle. The first axle is mounted to the body via a first slot and a second slot, with each slot extending generally in the direction in which the drive mechanism propels the vehicle such that the first axle can move toward either end of the slots. A steering structure is provided having a flexible member with at least a first portion which moves to close a portion of the first slot to limit the movement of the first axle in the first slot, the movement of the first portion changing the angle of the first axle to other than perpendicular to the directions in which the drive mechanism propels the vehicle when the first axle is used as the trailing axle. The steering structure has a locking mechanism which interacts with the body to hold the first portion in a position closing a portion of its slot.
Referring to
The rear wheels 40 are carried by an axle 80 (Shown in
The vehicle 10 is propelled forward and backwards on its front wheels 30 and back wheels 40 by the operation of the electric motor 12 and its associated propellers 14 expelling water out of one of its outlet ports 15. The direction of rotation of the electric motor 12 is reversed by its remote power source 18 causing the direction of water expulsion and the direction of travel of the vehicle to be reversed. The power source 18 is conveniently equipped with a timer which causes the reversal and the timer is conveniently set to the time it takes the vehicle to traverse a length or width of the surface being cleaned. Thus as the vehicle reaches an end of this surface, the timer of the power source 18 acts to reverse its general direction of travel. When the steering ribbon 50 is locked in a position such that it occludes a portion of one of the slots 90, it causes the back axle 80 to become tilted when the vehicle moves forward and this alters the direction of travel of the vehicle. In this way the vehicle traces a pattern that covers the entire surface to be cleaned rather than moving back and forth over the same path.
Referring to
When the vehicle 10 has completed its cleaning operation it is raised out of the reservoir of liquid covering the surface being cleaned and the liquid contained within the vehicle is permitted to drain out through the drainage slits 23. The inlet port flap valves 28 allow liquid to be drawn into the interior of the vehicle 10 by the action of the propellers 14 but not to allow it to drain out. On the other hand, the drainage slit flap valves 25 allow the liquid to drain out of the interior of the vehicle 10 when it is raised out of the reservoir but prevents the entrance of the fluid into the interior through the drainage slits 23 when the vehicle is submerged and the propellers 14 are in operation.
Referring to
The placement of the inlet ports 22 is to accommodate the filter system which in turn is configured to facilitate easy removal of the filter frame 110. The two inlet ports 22 are each placed on the opposite side of the centerline of the chassis 20 so that each can feed a separate filter frame 110 and yet the two together can cover the entire width of the chassis 20. The filter frames 110 are configured to be parallel to this center line so that they can be removed without interference with the electric motor 12 and its associated propellers 14.
Referring to
The handle 116 provides for the removal of the filter frame 110 for cleaning but also provides a locking function for holding the filter frame 110 in place during the cleaning operation of the vehicle 10. This locking function is provided by the interaction of the protrusions 122 carried by the filter handle 120 as can be seen in
The filter frame 110 is also provided with a door 111 which opens on hinges 115 as can be seen in
The bottom of the chassis has been provided with passive brushes 130 which can be seen in
In another embodiment, shown in
In a center setting where knob 52 is positioned midway or equidistant between the wheels 40 attached to axle 80, axel 80 will be perpendicular to the movement of the vehicle when the vehicle moves in a direction toward slide knob 52 as shown by vector 156. When the vehicle is moving in the direction of vector 156 axle 80 will be pushed by and adjacent to first ends 146 and 152 of first and second slots 142 and 144 respectively. Similarly, when the vehicle moves rearward in a direction opposite vector 156, axle 80 remains perpendicular to vector 156 with axle 80 being pushed by and adjacent to second ends 148 and 154 of first and second slots 142 and 144 respectively.
When a user moves slide knob 52 to a rightward position in vector direction 158, first end 146 of first slot 142 will pull axle 80 proximate slot 142 in vector direction 156. However, the portion of axle 80 proximate second slot 144 will be free to travel between first end 152 and second end 154 of second slot 144. In this configuration, when the vehicle is moving in vector direction 156, the axel 80 proximate first slot 142 will be in a fixed/restrained mode while the axle 80 proximate second slot 144 will have freedom to move toward the body opposite vector 156 such that axle 80 proximate second slot 144 will be adjacent first end 152 of second slot 144. As a result, the axle and wheels will be at a non-perpendicular angle relative to vector 156. This will result in the vehicle being steered or directed in a leftward motion with respect to vector 156. For purposes of clarity, the vector direction that the vehicle will move in this mode will be between vectors 156 and 158.
In this rightward mode when the vehicle is moved in a direction opposite to vector 156 axle 80 proximate first slot 142 will remain fixed relative to first end 146 of first slot 142 while the axle will be pushed to second end 154 of second slot 144. Hence making the axle perpendicular to vector 156. As a result the motion of the vehicle in the direction opposite to vector 156 will be straight, while the motion of the vehicle in the general direction of vector 156 will veer in a left ward direction between vectors 156 and 158 as noted above.
When a user moves slide knob 52 to a leftward position opposite to vector direction 158, first end 152 of second slot 144 will pull axle 80 proximate slot 144 in vector direction 156. However, the portion of axle 80 proximate first slot 142 will be free to travel between first end 146 and second end 148 of first slot 142. In this configuration, when the vehicle is moving in vector direction 156, the axel 80 proximate second slot 144 will be in a fixed/restrained mode while the axle 80 proximate first slot 142 will have freedom to move toward the body opposite vector 156 such that axle 80 proximate first slot 144 will be adjacent first end 146 of first slot 142. As a result, the axle and wheels will be at a non-perpendicular angle relative to vector 156. This will result in the vehicle being steered or directed in a rightward motion with respect to vector 156. For purposes of clarity, the vector direction that the vehicle will move in this mode will be between vectors 156 and 160.
In this leftward mode when the vehicle is moved in a direction opposite to vector 156 axle 80 proximate second slot 144 will remain fixed relative to first end 152 of second slot 144 while the axle 80 proximate first slot 142 will be pushed to second end 148 of first slot 142. Hence making the axle 80 perpendicular to vector 156. As a result the motion of the vehicle in the direction opposite to vector 156 will be straight, while the motion of the vehicle in the general direction of vector 156 will veer in a right ward direction between vectors 156 and 160 as noted above.
While only certain features of the invention have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention. It is noted that the construction and arrangement of the pool cleaning vehicle with mechanism for skewing an axle as described herein is illustrative only. Although only a few embodiments of the present invention have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g. variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters, mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited in the claims. For example, elements shown as integrally formed may be constructed of multiple parts or elements and vice versa, the position of elements may be reversed or otherwise varied, and the nature of number of discrete elements or positions may be altered or varied. Additionally, the mechanism for skewing the axle may also be applied to other pool cleaning vehicles including vehicles with wheels driven by a mechanical linkage to a motor, or to vehicles employing a single propeller. Accordingly, all such modifications are intended to be included within the scope of the present invention to be included within the scope of the present invention as defined in the appended claims. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present inventions as expressed in the appended claims.
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Number | Date | Country | |
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20140137891 A1 | May 2014 | US |