Autonomous or robotic floor cleaners can move without the assistance of a user or operator to clean a floor surface. For example, the floor cleaner can be configured to sweep dirt (including dust, hair, and other debris) into a collection bin carried on the floor cleaner and/or to sweep dirt using a cloth which collects the dirt. The floor cleaner can move randomly about a surface while cleaning the floor surface or use a mapping/navigation system for guided navigation about the surface. Some floor cleaners are further configured to apply and extract liquid for deep cleaning carpets, rugs, and other floor surfaces.
An aspect of the present disclosure relates to a cleaning system including an autonomous floor cleaner including an autonomously moveable housing, a fluid delivery system including a supply tank and a receiver coupling in fluid communication with the supply tank, a fluid recovery system including a recovery tank and a waste disposal coupling in fluid communication with the recovery tank wherein the fluid delivery and the fluid recovery systems are carried on the autonomously moveable housing and a controller operably coupled to at least one component or system of the autonomous floor cleaner and operate the at least one component or system according to an operation cycle, a docking station including a liquid supply system configured to fill a supply tank onboard the autonomous floor cleaner and including a supply conduit and a supply coupling configured to couple with a corresponding receiver coupling on the autonomous floor cleaner; and a disposal system configured to empty a recovery tank onboard the autonomous floor cleaner and including a waste receiver coupling configured to couple with a corresponding waste disposal coupling on the autonomous floor cleaner wherein the docking station is configured to be fluidly coupled to a plumbing infrastructure, and to fill the supply tank and to empty the recovery tank via the plumbing infrastructure.
Another aspect of the present disclosure relates to a cleaning system, including an appliance having a front side and a door with a docking station provided at the front side below the door, the docking station adapted for docking an autonomous floor cleaner, the docking station including a liquid supply system configured to fill a supply tank onboard the autonomous floor cleaner and including a supply conduit and a supply coupling configured to couple with a corresponding receiver coupling on the autonomous floor cleaner, a disposal system configured to empty a recovery tank onboard the autonomous floor cleaner and including a waste receiver coupling configured to couple with a corresponding waste disposal coupling on the autonomous floor cleaner and a charging system configured to recharge the autonomous floor cleaner wherein the docking station is configured to be fluidly coupled to a plumbing infrastructure, and to fill the supply tank and to empty the recovery tank via the plumbing infrastructure
The invention will now be described with respect to the drawings in which:
The invention relates to autonomous cleaners for deep cleaning floor surfaces, including carpets and rugs. More specifically, the invention relates to systems and methods for refilling (or filling) and emptying autonomous deep cleaners.
Optionally, an artificial barrier system 20 can also be provided with the system 5 for containing the robot 100 within a user-determined boundary. Also, optionally, the docking station 10 can further be connected to a household power supply, such as a wall outlet 14, and can include a converter 12 for converting the AC voltage into DC voltage for recharging a power supply on-board the robot 100. The docking station 10 can also include a housing 11 having various sensors and emitters for monitoring robot status, enabling auto-docking functionality, communicating with each robot, as well as features for network and/or Bluetooth connectivity.
The deep cleaning robot 100 mounts the components of various functional systems of the extraction cleaner in an autonomously moveable unit or housing 112 (
A controller 128 is operably coupled with the various functional systems of robot 100 for controlling its operation. The controller 128 can be a microcontroller unit (MCU) that contains at least one central processing unit (CPU).
The fluid delivery system can include the supply tank 106 for storing a supply of cleaning fluid and a fluid distributor 107 in fluid communication with the supply tank 106 for depositing a cleaning fluid onto the surface. The cleaning fluid can be a liquid such as water or a cleaning solution specifically formulated for carpet or hard surface cleaning. The fluid distributor 107 can be one or more spray nozzles provided on the housing 112 of the robot 100. Alternatively, the fluid distributor 107 can be a manifold having multiple outlets. A fluid delivery pump 105 is provided in the fluid pathway between the supply tank 106 and the fluid distributor 107 to control the flow of fluid to the fluid distributor 107. Various combinations of optional components can be incorporated into the fluid delivery system as is commonly known in the art, such as a heater for heating the cleaning fluid before it is applied to the surface or one more fluid control and mixing valves.
At least one agitator or brush 140 can be provided for agitating the surface to be cleaned onto which fluid has been dispensed. The brush 140 can be a brushroll mounted for rotation about a substantially horizontal axis, relative to the surface over which the robot 100 moves. A drive assembly including a separate, dedicated brush motor 142 can be provided within the robot 100 to drive the brush 140. Alternatively, the brush 140 can be driven by a vacuum motor 116. Other embodiments of agitators are also possible, including one or more stationary or non-moving brushes, or one or more brushes that rotate about a substantially vertical axis.
The fluid recovery system can include an extraction path through the robot 100 having an air inlet and an air outlet, an extraction or suction nozzle 114 which is positioned to confront the surface to be cleaned and defines the air inlet, the recovery tank 118 for receiving dirt and liquid removed from the surface for later disposal, and a suction source 116 in fluid communication with the suction nozzle 114 and the recovery tank 118 for generating a working air stream through the extraction path. The suction source 116 can be the vacuum motor 116 carried by the robot 100, fluidly upstream of the air outlet, and can define a portion of the extraction path. The recovery tank 118 can also define a portion of the extraction path and can comprise an air/liquid separator for separating liquid from the working airstream. Optionally, a pre-motor filter and/or a post-motor filter (not shown) can be provided as well.
While not shown, a squeegee can be provided on the housing 112 of the robot 100, adjacent the suction nozzle 114, and is configured to contact the surface as the robot 100 moves across the surface to be cleaned. The squeegee wipes residual liquid from the surface to be cleaned so that it can be drawn into the fluid recovery pathway via the suction nozzle 114, thereby leaving a moisture and streak-free finish on the surface to be cleaned.
The drive system can include drive wheels 130 for driving the robot 100 across a surface to be cleaned. The drive wheels 130 can be operated by a common drive motor or individual drive motors 131 coupled with the drive wheels 130 by a transmission, which may include a gear train assembly or another suitable transmission. The drive system can receive inputs from the controller 128 for driving the robot 100 across a floor, based on inputs from the navigation/mapping system. The drive wheels 130 can be driven in a forward or reverse direction in order to move the unit forwardly or rearwardly. Furthermore, the drive wheels can be operated simultaneously or individually in order to turn the unit in a desired direction.
The controller 128 can receive input from the navigation/mapping system for directing the drive system to move the robot 100 over the surface to be cleaned. The navigation/mapping system can include a memory 168 that stores maps for navigation and inputs from various sensors, which is used to guide the movement of the robot 100. For example, wheel encoders 172 can be placed on the drive shafts of the wheel motors 131 and are configured to measure the distance travelled. This measurement can be provided as input to the controller 128.
Motor drivers 103, 146, 144, and 148 can be provided for controlling the pump 105, brush motor 142, vacuum motor 116, and wheel motors 131, respectively, and act as an interface between the controller 128 and the motors 105, 142, 116, 131. The motor drivers 103, 146, 144, and 148 may be an integrated circuit chip (IC). For the wheel motors 131, one motor driver 148 can control the motors 131 simultaneously.
The motor drivers 103, 146, 144, and 148 for the pump 105, brush motor 142, vacuum motor 116, and wheel motors 131 can be electrically coupled to a battery management system 150 which includes a rechargeable battery or battery pack 152. In one example, the battery pack 152 can include lithium ion batteries. Charging contacts for the battery pack 152 can be provided on the exterior of the unit 112. The docking station 10 (
The controller 128 is further operably coupled with a user interface (UI) 124 for receiving inputs from a user. The user interface 124 can be used to select an operation cycle for the robot 100 or otherwise control the operation of the robot 100. The user interface 124 can have a display 156, such as an LED display, for providing visual notifications to the user. A display driver 158 can be provided for controlling the display 156, and acts as an interface between the controller 128 and the display 156. The display driver 158 may be an integrated circuit chip (IC). The robot 100 can further be provided with a speaker (not shown) for providing audible notifications to the user.
The user interface 124 can further have one or more switches 126 that are actuated by the user to provide input to the controller 128 to control the operation of various components of the robot 100. The switches 126 can be actuated by a button, toggle, or any other suitable actuating mechanism. A switch driver 125 can be provided for controlling the switch 126, and acts as an interface between the controller 128 and the switch 126.
The controller 128 can further be operably coupled with various sensors for receiving input about the environment and can use the sensor input to control the operation of the robot 100. The sensor input can further be stored in the memory 168 and/or used to develop maps for navigation. Some exemplary sensors are illustrated in
The robot 100 can include a positioning or localization system having one or more sensors determining the position of the robot relative to objects. The localization system can include one or more infrared (IR) obstacle sensors 170 for distance and position sensing. The obstacle sensors 170 can be mounted to the housing 112 of the robot 100, such as in the front of robot 100 to determine the distance to obstacles in front of the robot 100. Input from the obstacle sensors 170 can be used to slow down and/or adjust the course of the robot 100 when objects are detected.
Bump sensors 174 can also be provided for determining front or side impacts to the robot 100. The bump sensors 174 may be integrated with a bumper on the housing 112 of the robot 100. Output signals from the bump sensors 174 provide inputs to the controller 128 for selecting an obstacle avoidance algorithm.
In addition to the obstacle and bump sensors 170, 174, the localization system can include additional sensors, including a side wall sensor 176, one or more cliff sensors 180, and/or an accelerometer 178. The side wall or wall following sensor 176 can be located near the side of the robot 100 and can include a side-facing optical position sensor that provides distance feedback and controls the robot 100 so that the robot 100 can follow near a wall without contacting the wall. The cliff sensors 180 can be bottom-facing optical position sensors that provide distance feedback and control the robot 100 so that the robot 100 can avoid excessive drops such as stairwells or ledges. In addition to optical sensors, the wall following and cliff sensors 176, 180 can be mechanical or ultrasonic sensors.
The accelerometer 178 can be an integrated inertial sensor located on the controller 128 and can be a nine-axis gyroscope or accelerometer to sense linear, rotational and magnetic field acceleration. The accelerometer 178 can use acceleration input data to calculate and communicate change in velocity and pose to the controller 128 for navigating the robot 100 around the surface to be cleaned.
The robot 100 can further include one or more lift-up sensors 182, which detect when the robot 100 is lifted off the surface to be cleaned, such as when the user picks up the robot 100. This information is provided as an input to the controller 128, which will halt operation of the pump 105, brush motor 142, vacuum motor 116, and/or wheel motors 131. The lift-up sensors 182 can also detect when the robot 100 is in contact with the surface to be cleaned, such as when the user places the robot 100 back on the ground; upon such input, the controller 128 may resume operation of the pump 105, brush motor 142, vacuum motor 116, and wheel motors 131.
While not shown, the robot 100 can optionally include one or more sensors for detecting the presence of the supply 106 and recovery 118 tanks. For example, one or more pressure sensors for detecting the weight of the supply tank 106 and the recovery tank 118 can be provided. This information is provided as an input to the controller 128, which may prevent operation of the robot 100 until the supply 106 and recovery 118 tanks are properly installed. The controller 128 may also direct the display 156 to provide a notification to the user that the supply tank 106 or recovery tank 118 is missing.
The robot 100 can further include one or more floor condition sensors 186 for detecting a condition of the surface to be cleaned. For example, the robot 100 can be provided with an infrared dirt sensor, a stain sensor, an odor sensor, and/or a wet mess sensor. The floor condition sensors 186 provide input to the controller 128, which may direct operation of the robot 100 based on the condition of the surface to be cleaned, such as by selecting or modifying a cleaning cycle.
As discussed briefly for the system of
The robot 100 can have a plurality of IR transceivers 192 around the perimeter of the robot 100 to sense the IR signals emitted from the artificial barrier system 20 and output corresponding signals to the controller 128, which can adjust drive wheel 130 control parameters to adjust the position of the robot 100 to avoid the boundaries established by the artificial barrier encoded IR beam and the short field IR beams. This prevents the robot 100 from crossing the artificial barrier boundary and/or colliding with the artificial barrier generator housing. The IR transceivers 192 can also be used to guide the robot 100 toward the docking station 10 (
In operation, sound emitted from the robot 100 greater than a predetermined threshold sound level is sensed by the microphone and triggers the artificial barrier generator to emit one or more encoded IR beams as described previously for a predetermined period of time. The IR transceivers 192 on the robot 100 sense the IR beams and output signals to the controller 128, which then manipulates the drive system to adjust the position of the robot 100 to avoid the border established by the artificial barrier system 20 while continuing to perform a cleaning operation on the surface to be cleaned.
With reference to
The docking station 10 integrated with the toilet 30 can include a liquid supply system for refilling the supply tank 106 of the robot 100, and a disposal system for emptying the recovery tank 118 of the robot 100. Embodiments of a liquid supply system of the docking station 10 are shown in
An existing toilet 30 can be retrofitted with a docking station 10 according to any of the embodiments discussed herein using an after-market kit. Alternatively, a toilet 30 can be supplied with an integrated docking station 10 from the manufacturer, according to any of the embodiments discussed herein.
Turning to
The tank contains reserve water 33 for refilling the bowl 32, plus mechanisms for flushing the bowl 32 and refilling the tank 34. A handle 44 on the exterior of the tank 34 is used as an actuator for the flushing mechanism and is operably coupled with a flush valve 46 which normally closes an outlet orifice of the tank 34.
When the toilet 30 is flushed by rotating the handle 44, the flush valve 46 opens and water from the tank 34 enters the bowl 32 quickly to activate the siphon 36. The water can enter the bowl 32 via holes in a rim 48 of the bowl 32. The waste and water from the bowl 32 is sucked into the drain 38, which may connect to a septic tank or a system connected to a sewage treatment plant.
Once the tank 34 has emptied, the flush valve 46 closes so that the tank 34 can be refilled by the refill mechanism. The refill mechanism can include a float 50 coupled with a fill valve 52 that turns the supply of water on and off. The fill valve 52 turns the supply of water on when the water level in the tank 34 drops and the float falls. The fill valve 52 sends water into the tank 34, and also into the bowl 32 via an overflow tube 54. When the water level in the tank 34 rises to a predetermined level, the float 50 closes the fill valve 52 and turns the supply of water off.
A liquid supply system 8 for the docking station 10 can include a supply conduit 56 that draws water from the toilet tank 34, which provides a low-pressure source of water for refilling the robot 100, and a water supply coupling 16 on a housing 11 of the docking station 10 configured to mate or otherwise couple with a corresponding water receiver coupling 132 on the robot 100.
The supply conduit 56 can provide water from the toilet tank 34 to the water supply coupling 16. The water receiver coupling 132 on the robot 100 can be in fluid communication with the robot supply tank 106, such that fluid received by the receiver coupling 132 is provided to the robot supply tank 106.
The robot 100 can include a fill pump 134 for drawing clean water from the toilet tank 34 into the robot supply tank 106 via the supply conduit 56 and, optionally, one or more additional conduits (not shown) fluidly coupling the components of the robot 100 together. The robot fill pump 134 can be provided in addition to the fluid delivery pump 105 (
Optionally, the docking station 10 can include a shut-off valve 18 for closing the fluid pathway through the supply conduit 56 when the robot 100 is not docked with the docking station 10. The shut-off valve 18 can be configured to automatically open when the robot 100 is docked with the docking station 10. For example, the shut-off valve 18 can be mechanically engaged by a portion of the robot 100, or more specifically by a portion of the water receiver coupling 132, to open a fluid pathway between the supply conduit 56 and the supply tank 106.
In one example, shown in
In another example, shown in
In operation and referring back to
The fill pump 134 can be automatically energized upon a successful docking between the robot 100 and the docking station 10. In one example, once the robot 100 docks successfully, a filling cycle or mode of operation can be initiated. Prior to initiation of the filling mode, the robot 100 may send a confirmation signal to the docking station 10 indicating that the robot 100 has successfully docked and is ready to commence filling. For example, an RF signal can be sent from the robot 100 to the docking station 10, and back to the robot 100. Alternatively, a pulsed signal can be sent through a charging pathway between the corresponding charging contacts for the battery pack 152 (
The filling mode is preferably automatically initiated after the confirmation signal is sent. The filling mode can be controlled by the controller 128 on the robot (
Alternatively, the filling mode can be manually initiated, with the user initiating the servicing mode by pressing a button on the user interface 124 (
The fill pump 134 can be automatically de-energized when the robot supply tank 106 is full. For example, the supply tank 106 can be provided with a fluid level sensor (not shown) that communicates with the controller 128 on the robot 100 when the supply tank 106 is full and filling is complete.
A water supply coupling 316 on a housing 311 of the docking station 310 is configured to mate or otherwise couple with a corresponding water receiver coupling 132 on the robot 100. The supply conduit 356 provides water from the water line 340 to the water supply coupling 316. The water receiver coupling 132 on the robot 100 is in fluid communication with the robot supply tank 106, such that fluid received by the water receiver coupling is provided to the robot supply tank 106.
The docking station 310 further can include an intermediate reservoir with a float-style shut-off valve similar to the float 350 shut-off assembly in the toilet tank. One example of an intermediate reservoir 360 and float-style shut-off valve 318 is shown in more detail in
In operation and referring back to
The fill pump 134 may be automatically energized upon a successful docking between the robot 100 and the docking station 310 and may be automatically de-energized when the robot supply tank 106 is full, as described above with respect to the liquid supply system 308 of
Filling from the intermediate reservoir 360, rather than directly from the toilet tank 334, may reduce coupling issues between the robot 100 and docking station 310. The intermediate reservoir 360 also has less head pressure from gravity as compared with the higher toilet tank 334. The docking station 310 with intermediate reservoir 360 can also be readily adaptable to other appliances, including but not limited to a dishwasher, refrigerator, washing machine, humidifier, or clothes dryer.
The disposal system 409 further includes a waste receiver coupling 415 on a housing 411 of the docking station 410 configured to mate or otherwise couple with a corresponding waste disposal coupling 136 on the robot. The disposal conduit 458 carries waste from the recovery tank 118 to the toilet plumbing downstream from the siphon 436 and upstream of the drain 438. The waste disposal coupling 136 on the robot 100 is in fluid communication with the robot recovery tank 118, such that waste collected by the recovery tank 118 can be disposed of by the disposal system via the docked or mated couplings 415, 136. The inlet side of the disposal pump 472 is coupled with the waste receiver coupling 415, while the outlet side of the disposal pump 472 is coupled with the disposal conduit 458.
Optionally, one or more additional conduits (not shown) can fluidly couple the components of the robot 100 together and/or the components of the docking station 410 together. Alternatively, for the robot 100, the waste disposal coupling 415 can be provided directly on the recovery tank 118 and can be configured to close an outlet of the recovery tank 118 when the robot 100 is not docked with the docking station 410 and further be configured to open the outlet of the recovery tank 118 when the robot 100 is docked with the docking station 410.
Optionally, the handle 444 of the toilet 430 can be an automated handle configured for communication with the robot 100 or docking station 410. During or after waste evacuation from the robot 100, the robot 100 or docking station 410 can send a signal to the automated handle to flush the toilet 430. The toilet 430 can also optionally be provided with a bowl level sensor 474 to prevent waste from filling a clogged toilet 430.
In operation, in a successful docking between the robot 100 and the docking station 410, the waste disposal coupling 136 on the robot 100 mates or otherwise fluidly couples with the waste receiver coupling 415 of the docking station 410. Next, the disposal pump 472 in the docking station 410 energizes and creates suction to draw waste from the recovery tank 118 through the disposal conduit 458, and into the drain 438 of the toilet 430, which may connect to a septic tank or a system connected to a sewage treatment plant.
The disposal pump 472 can be automatically energized upon a successful docking between the robot 100 and the docking station 410. In one example, once the robot 100 docks successfully, an emptying cycle or mode of operation can be initiated. Prior to initiation of the emptying mode, the robot 100 can send a confirmation signal to the docking station 410 indicating that the robot 100 has successfully docked and is ready to commence emptying. For example, an RF signal can be sent from the robot 100 to the docking station 410, and back to the robot 100. Alternatively, a pulsed signal can be sent through the charging pathway between the corresponding charging contacts for the battery pack 152 (
The emptying mode is preferably automatically initiated after the confirmation signal is sent. The emptying mode can be controlled by a controller (not shown) on the docking station 410 and can automatically initiate once the robot 100 is confirmed to be docked in the docking station 410.
Alternatively, the emptying mode can be manually initiated, with the user initiating the emptying mode by pressing a button on the user interface 124 (
The disposal pump 472 can be automatically de-energized when the robot recovery tank 118 is empty. For example, the recovery tank 118 can be provided with a level sensor (not shown) that communicates with the controller on the docking station 410 when the recovery tank 118 is empty and emptying is complete.
A valve 580 is provided between the disposal conduit 577 and the passageway between the siphon 536 and drain 538 of the toilet 530, at the outlet of the disposal conduit 577 or inlet to the passageway. In one example, the valve 580 can comprise a flapper valve adapted to create a water-tight seal at the inlet to the passageway before and after waste is evacuated from the robot 100. When the disposal pump 578 is energized and waste flows through the disposal conduit 577, the flapper valve 580 opens, allowing the waste to flow into the passageway between the siphon 536 and drain 538 of the toilet 530. After, the flapper valve 580 closes and reforms the water-tight seal.
The disposal pump 578 can mount to the toilet 530 separately from the docking station 510. In the example illustrated herein, the disposal pump 578 can be mounted to the rear of the toilet 530, beneath the tank 534. Other mounting locations are possible, such as to the side of the toilet 530 or tank 534, or within the tank 534 itself.
Optionally, one or more additional conduits (not shown) can fluidly couple the components of the robot 100 together and/or the components of the docking station 510 together. Alternatively, for the robot 100, the waste disposal coupling 136 can be provided directly on the recovery tank 118 and can be configured to close an outlet of the recovery tank 118 when the robot 100 is not docked with the docking station 510 and further be configured to open the outlet of the recovery tank 118 when the robot 100 is docked with the docking station 510.
In operation, in a successful docking between the robot 100 and the docking station 510, the waste disposal coupling 136 on the robot 100 mates or otherwise fluidly couples with the waste receiver coupling 515 of the docking station 510. Next, the disposal pump 578 on the toilet 530 energizes and creates suction to draw waste from the recovery tank 118 through the evacuation conduit 576, disposal pump 578, and disposal conduit 577, and into the drain 538 of the toilet 530, which may connect to a septic tank or a system connected to a sewage treatment plant.
The disposal pump 578 can be automatically energized upon a successful docking between the robot 100 and the docking station 510. In one example, once the robot 100 docks successfully, an emptying cycle or mode of operation can be initiated, and the docking station 510 can be in communication with the disposal pump 578 to initiate the emptying mode. Prior to initiation of the emptying mode, the robot 100 may send a confirmation signal to the docking station 510 indicating that the robot 100 has successfully docked and is ready to commence emptying. For example, an RF signal can be sent from the robot 100 to the docking station 510, and back to the robot 100. Alternatively, a pulsed signal can be sent through the charging pathway between the charging contacts for the battery pack 152 (
The emptying mode is preferably automatically initiated after the confirmation signal is sent. The emptying mode can be controlled by a controller on the docking station 510 and can automatically initiate once the robot 100 is confirmed to be docked in the docking station 510.
Alternatively, the emptying mode can be manually initiated, with the user initiating the emptying mode by pressing a button on the user interface 124 (
The disposal pump 578 can be automatically de-energized when the robot recovery tank 118 is empty. For example, the recovery tank 118 can be provided with a level sensor that communicates with the controller on the docking station 510 when the recovery tank 118 is empty and emptying is complete.
The docking station 610 can be connected to a household power supply, such as a wall outlet 614, by a power cord 682. The docking station 610 can further include a converter 612 for converting AC voltage from the wall outlet 614 into DC voltage for recharging a power supply on-board the robot 100. The docking station 610 can also include various sensors and emitters for monitoring robot status, enabling auto-docking functionality, communicating with each robot, as well as features for network and/or Bluetooth connectivity.
In operation, in a successful docking between the robot 100 and the docking station 610, the charging contacts 154 on the robot 100 mate or otherwise electrically couple with the charging contacts 684 of the docking station 610. The toilet 630 can be provided with the recharging function in addition to the supply and/or disposal functions discussed above. As such, the battery 152 of the robot 100 can be recharged when the robot 100 docks with the toilet 630 for supply or disposal.
Docking the robot 100 with the docking station 10 can include one or more of: making a fluid connection between the supply tank 106 of the robot 100 and the liquid supply system of the docking station 10; making a fluid connection between the recovery tank 118 of the robot 100 and the disposal system of the docking station 10; and/or making an electrical connection between the charging contacts 154, 684 (
Once docked, a servicing cycle or mode of operation can be initiated. Prior to initiation of the serving mode, the robot 100 can send a confirmation signal to the docking station 10 indicating that the robot 100 has successfully docked at step 740 and is ready to commence refilling and emptying. For example, an RF signal can be sent from the robot 100 to the docking station 10, and back to the robot 100. Alternatively, a pulsed signal can be sent through the charging pathway between the charging contacts 154, 684. As yet another alternative, an IR signal can be sent to be robot 100 to an IR receiver on the docking station 10.
A servicing mode is preferably automatically initiated after the confirmation signal is sent at 740. The servicing mode can be controlled by the controller 128 on the robot 100 (
Alternatively, the servicing mode can be manually initiated, with the user initiating the servicing mode by pressing a button on the user interface 124 (
The servicing mode can include a refilling phase at step 750 in which water is delivered from the docking station to the supply tank of the robot. The servicing mode can also include an emptying phase at step 760 in which waste in the recovery tank 118 is emptied to the toilet 30 via the docking station 10. The servicing mode may also include a recharging phase at step 770 in which the battery 152 of the robot 100 is recharged via the docking station 10.
The refilling, emptying and/or recharging phases of the servicing mode may be performed simultaneously or sequentially, in any order and with any amount of overlap between the two phases. In yet another alternative, one of the phases can initiate after a timed delay from the initiation of the other phase.
The end of steps 750, 760, and 770 may be time-dependent, or may continue until the supply tank 106 is full, the recovery tank 118 is empty, and/or the battery 152 is recharged. After the end 780 of the servicing mode, the docked deep cleaning robot 100 can undock to resume cleaning or may remain docked until another cleaning operation is required.
While the method shown in
The deep cleaning robot 100 of
The dishwasher 830 includes a wash chamber 834 provided with a sump 836 at a lower part of the wash chamber 834. During operation of the dishwasher 830, water sprayed on dishes in the wash chamber 834 flows downwardly and collects in the sump 836. A pump 840 is provided in fluid communication with the sump 836 for directing liquid in the sump 836 to a drain line 842. A separate wash pump (not shown) can be provided for recirculating liquid in the sump 836 back into the wash chamber 834, or the pump 840 shown in
The disposal system 800 can include the dishwasher pump 840, a waste receiver coupling 815 on a housing or cabinet of the dishwasher 830 that is configured to mate or otherwise couple with a corresponding waste disposal coupling 136 on the robot 100, and an evacuation conduit 876 in fluid communication with the waste receiver coupling 815. The docking station 810 of the dishwasher 830, particularly the waste receiver coupling 815, can be provided at a front side of the dishwasher 830, such as below a door 832 of the dishwasher 830 or adjacent to the dishwasher 830 in a cabinet toe kick 835. The waste disposal coupling 136 on the robot 100 is in fluid communication with the robot recovery tank 118, such that waste collected by the recovery tank 118 can be disposed of by the disposal system via the docked or mated couplings 136, 815. The evacuation conduit 876 has an outlet end fluidly coupled to the inlet side of the pump 840. The evacuation conduit 876 can be vacuum pressurized by the pump 840 and can carry waste from the recovery tank 118 to the pump 840, and on to the drain line 842, also pressurized by the pump 840.
As shown, the drain line 842 can be fluidly coupled with a garbage disposal 852 associated with a sink 850. The drain line 842 thereby carries waste from the recovery tank 118 to the garbage disposal 852. The outlet of the garbage disposal 852 is fluidly coupled with a trap 854. The trap 854 may be fluidly coupled with a septic tank or a system connected to a sewage treatment plant.
Optionally, one or more additional conduits (not shown) can fluidly couple the components of the robot 100 together and/or the components of the docking station 810 or dishwasher 830 together. Alternatively, for the robot 100, the waste disposal coupling 136 can be provided directly on the recovery tank 118 and can be configured to close an outlet of the recovery tank 118 when the robot 100 is not docked with the docking station 810 and further be configured to open the outlet of the recovery tank 118 when the robot 100 is docked with the docking station 810.
The disposal system can be optionally provided with a diverter valve 838 configured to divert the fluid pathway to the dishwasher pump 840 between either of the dishwasher sump 836 and the robot 100. In one example, shown in
In operation, in a successful docking between the robot 100 and the docking station 810, the waste disposal coupling 136 on the robot mates or otherwise fluidly couples with the waste receiver coupling 815 of the docking station 810. Next, the dishwasher pump 840 energizes and creates suction to draw waste from the recovery tank 118 through the evacuation conduit 876, and into the drain line 842 of the dishwasher 830.
The dishwasher pump 840 can be automatically energized upon a successful docking between the robot 100 and the docking station 810. In one example, once the robot 100 docks successfully, an emptying cycle or mode of operation can be initiated. Prior to initiation of the emptying mode, the robot 100 can send a confirmation signal to the docking station 810 indicating that the robot 100 has successfully docked and is ready to commence emptying. For example, an RF signal can be sent from the robot 100 to the docking station 810, and back to the robot 100. Alternatively, a pulsed signal can be sent through the charging pathway between the charging contacts for the battery pack 152 (
The emptying mode is preferably automatically initiated after the confirmation signal is sent. The emptying mode can be controlled by a controller on the docking station 810 or by a controller on the dishwasher 830, and automatically initiates once the robot 100 is confirmed to be docked in the docking station 810. The initiation of the emptying mode may be automatically delayed if the dishwasher 830 is performing a dishwashing cycle when the robot 100 docks.
Alternatively, the emptying mode can be manually initiated, with the user initiating the emptying mode by pressing a button on the user interface 124 (
The dishwasher pump 840 may be automatically de-energized when the robot 100 recovery tank 118 is empty. For example, the recovery tank 118 can be provided with a level sensor that communicates with a controller on the docking station 810 or dishwasher 830 when the recovery tank 118 is empty and emptying is complete.
It is noted that while the dishwasher 830 of the illustrated embodiment is shown as draining via a garbage disposal 852, this is not required in all embodiments of the system 800, and in other examples the drain line 842 can drain to another line, such as directly to the sink 850 drain pipe or trap 854. It is also noted that the system 800 can include an air gap (not shown) to prevent the back flow of liquid into the dishwasher 830.
While the system 800 is shown with a dishwasher 830 having the docking station 810 for the robot 100, it is understood that the systems of any of the embodiments shown herein can have a docking station for the robot 100 provided on another appliance. Some non-limiting examples of appliances in addition to a dishwasher 830 include a refrigerator, a washing machine, a humidifier, and a clothes dryer.
In the exemplary docking stations 10, 210, 310, 410, 510, 810 described herein, fluid couplings on the robot 100 and the docking stations 10, 210, 310, 410, 510, 810 mate when the robot 100 is docked in the docking station 10, 210, 310, 410, 510, 810 to direct liquid between the robot 100 and docking station 10, 210, 310, 410, 510, 810. For example, the liquid supply system of the exemplary docking stations 10, 210, 310 described herein include a water supply coupling on a housing of the docking station configured to mate or otherwise couple with the corresponding water receiver coupling 132 on the robot 100, and the disposal system of the exemplary docking stations 410, 510, 810 described herein include a waste receiver coupling on a housing of the docking station configured to mate or otherwise couple with the corresponding waste disposal coupling 136 on the robot 100.
In
Optionally, a seal 932 is provided at the interface between the male and female couplings 920, 910 to prevent liquid from escaping from the fluid coupling assembly 900. Negative pressure applied by the pump 940 can also reinforce the seal 932 between the male and female couplings 920, 910.
Depending on whether the fluid coupling assembly 900 is used for a liquid supply system or disposal system, of the docking station, the female receiver, or female coupling 910, can be provided on the docking station 10 (
In
With reference to
The docking station 1110 can be provided at a front lower side of the household appliance 1100, which can include a door 1114, such that a deep cleaning robot 100 can drive up to the household appliance 1100 and dock with the docking station 1110. The household appliance may include, but is not limited to, a dishwasher, refrigerator, washing machine, humidifier or clothes dryer. For illustrative purposes, the household appliance 1100 is shown as a dishwasher, and the docking station is provided below the door 1114 of the dishwasher.
The deep cleaning robot 100 is provided with a trim piece 1120 that matches the area of the appliance surrounding the docking station. For example, the trim piece 1120 may match the material, color, and finish of an appliance panel, grill, toe kick 1112 or other component. The trim piece 1120 can additionally or alternatively match the shape of the docking station 1110 such that when the robot 100 docks with the docking station 1110, as shown in
The deep cleaning robot 100 can be provided with the trim piece 1120 by the manufacturer, or after-market kits can be provided to let users select a suitable trim piece 1120 and to apply it to the robot 100. In one non-limiting example, the deep cleaning robot 100 can have an overall D-shape, with a flat wall. The trim piece 1120 can be provided on the flat wall of the robot 100.
In
The deep cleaning robot 100 can be provided with a trim piece 1220 that matches the area of the cabinet 1200 surrounding the docking station 1210. For example, the trim piece 1220 may match the material, color, and finish of the cabinet toe kick 1212, drawer 1214, or sidewall 1216. The trim piece 1220 can additionally or alternatively match the shape of the docking station 1210 such that when the robot 100 docks with the docking station 1210, as shown in
The deep cleaning robot can be provided with the trim piece 1220 by the manufacturer, or after-market kits can be provided to let users select a suitable trim piece 1220 and to apply it to the robot 100. Other kits could come with a range of trim piece panels to match or contrast the cabinet 1200. In one non-limiting example, the deep cleaning robot 100 can have an overall D-shape, with a flat wall. The trim piece 1220 can be provided on the flat wall of the robot 100.
There are several advantages of the present disclosure arising from the various features of the apparatuses described herein. For example, the embodiments of the invention described above provides automated filling and emptying of an autonomous deep cleaning robot. Deep cleaners currently available must be manually filled and emptied by the user, sometimes more than once during a cleaning operation if cleaning an area larger than the capacity of the tanks. The automated supply and disposal system disclosed in the embodiment herein offer long term automation of a cleaning operation that includes automation of the emptying and refilling operations, which will allow cleaning to continue without requiring interaction by or even the presence of the user.
Another advantage of some embodiments of the present disclosure is that the system leverages the existing infrastructure already found in most homes and other buildings, and uses a toilet to supply cleaning fluid to, evacuate waste from, and/or recharge the battery of a deep cleaning robot.
Yet another advantage of some embodiments of the present disclosure is that the system leverages the existing infrastructure already found in most homes and other buildings, and uses a dishwasher to evacuate waste from a deep cleaning robot.
It is further noted that the docking station disclosed in any embodiment of the present disclosure can be built into the toilet, dishwasher, or other household appliance, or retrofitted to an existing toilet, dishwasher, or other household appliance. Users try to find places to hide their autonomous cleaners with limited success. Autonomous cleaners and their charging stations need to be accessible to the space being cleaned. This combination is often unsightly and cumbersome to step over. Aspects of the present disclosure offer a solution to at least partially hide the robot away when not being used and takes up space that is usually not utilized.
While various embodiments illustrated herein show an autonomous or robotic cleaner, aspects of the invention such as the supply and disposal docking station may be used on other types floor cleaners having liquid supply and extraction systems, including non-autonomous cleaners. Still further, aspects of the present disclosure may also be used on surface cleaning apparatus other than deep cleaners, such as an apparatus configured to deliver steam rather than liquid.
To the extent not already described, the different features and structures of the various embodiments disclosed herein may be used in combination with each other as desired. That one feature may not be illustrated in all of the embodiments is not meant to be construed that it cannot be, but is done for brevity of description. Thus, the various features of the different embodiments may be mixed and matched as desired to form new embodiments, whether or not the new embodiments are expressly described.
While the invention has been specifically described in connection with certain specific embodiments thereof, it is to be understood that this is by way of illustration and not of limitation. Reasonable variation and modification are possible with the scope of the foregoing disclosure and drawings without departing from the spirit of the invention which, is defined in the appended claims. Hence, specific dimensions and other physical characteristics relating to the embodiments disclosed herein are not to be considered as limiting, unless the claims expressly state otherwise.
This application is a continuation of U.S. patent application Ser. No. 16/018,345 filed Jun. 26, 2018, now U.S. Pat. No. 10,709,308, issued Jul. 14, 2020, which claims the benefit of U.S. Provisional Patent Application No. 62/525,383, filed Jun. 27, 2017, all of which are incorporated herein by reference in their entirety.
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Number | Date | Country | |
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Parent | 16018345 | Jun 2018 | US |
Child | 16922615 | US |