A cleaning system includes a robotic cleaner and an evacuation station. The robotic cleaner can dock with the evacuation station to have debris evacuated by the evacuation station. The robotic cleaner includes a bin to store debris, and the bin includes a port door through which the debris can be evacuated into the evacuation station. The evacuation station includes a vacuum motor to evacuate the bin of the robotic cleaner.

In general, the present disclosure is directed to a hand-held surface cleaning device that includes a relatively compact form-factor to allow users to store the same in a nearby location (e.g., in a drawer, in an associated charging dock, on a table top) for easy access to perform relatively small cleaning tasks that would otherwise require retrieving a full-size vacuum from storage. A hand-held surface cleaning device consistent with aspects of the present disclosure includes a body (or body portion) with a motor, power source and dust cup disposed therein. The body portion also functions as a handgrip to allow the hand-held surface cleaning device to be operated by one hand, for example.

An autonomous vacuum cleaner that can reduce the footprint in a standby state is provided. An autonomous vacuum cleaner (1) includes a vacuum cleaner body (2) and a charging station (6). The charging station (6) has a hook (64) that latches a latched member (16) provided to a rear side of the vacuum cleaner body (2), and a lift driver (61) that raises and lowers the hook (64), and is configured to be capable of storing the vacuum cleaner body (2) in a standing state where the vacuum cleaner body (2) is hoisted and the rear side is oriented upward.

A debris monitoring system includes a receptacle, a first and a second emitter, and a first receiver. The receptacle defines an opening to receive debris into the receptacle. The first and second emitter are each arranged to emit a signal across at least a portion of the opening. The first receiver is proximate to the first emitter to receive reflections of the signal emitted by the first emitter, and the first receiver is disposed toward the opening to receive an unreflected portion of the signal emitted by the second emitter across at least a portion of the opening.

A method for energy management robotic device includes providing a base station for mating with the robotic device, determining a quantity of energy stored in an energy storage unit of the robotic device, and performing a predetermined task based at least in part on the quantity of energy stored. Also disclosed are systems for emitting avoidance signals to prevent inadvertent contact between the robot and the base station, and systems for emitting homing signals to allow the robotic device to accurately dock with the base station.

A mobile robot system includes a docking station and a mobile robot. The docking station includes a platform, first and second charging contacts on the platform, and first and second ramp features on the platform. The robot includes a housing, first and second drive wheels, first and second raised charging contacts on a bottom of the housing, and a cleaning module including at least one rotatable cleaning head that extends below the bottom of the housing. The robot is movable from an approach position with the robot spaced apart from a front of the platform to a docked position with the robot on the platform and the docking station charging contacts engaged with the robot charging contacts. As the robot moves from the approach position to the docked position, the robot engages the first and second ramp features and the cleaning mechanism is lifted over the docking station charging contacts.

A self-propelled electronic device including: at least one drive wheel disposed at a bottom of a housing, the drive wheel traveling the housing while being displaced in a vertical direction in accordance with undulations of a floor surface; a drive wheel sensor for detecting a position of the drive wheel relative to the housing; a floor detection sensor for detecting a distance between the bottom of the housing and the floor surface; and a travel control unit for determining and deciding a course of the housing based on the determination that there exists a step on the floor surface if the distance detected by the floor detection sensor is longer than a predetermined reference distance, or, otherwise, the position of the drive wheel detected by the drive wheel sensor is lower than a predetermined reference position, by successively referring to output of the drive wheel sensor and the floor detection sensor, wherein, if the position of the drive wheel detected by the drive wheel sensor is lower than a predetermined reference position, the travel control unit further refers to the distance detected by the floor detection sensor, and if the distance detected by the floor detection sensor is longer than the predetermined reference distance, the travel control unit perform the avoidance traveling control of the housing to avoid the step, and travels the housing, whereas, if the distance detected by the floor detection sensor is the predetermined reference distance or shorter, the travel control unit does not perform the avoidance traveling control of the housing, and continues the traveling of the housing.

A vacuum cleaner system includes a docking station and a mobile vacuum cleaner. The docking station includes a charging stand and a parking plate. The parking plate is connected to the charging stand, and formed with two position-limiting slots. The mobile vacuum cleaner includes a working machine body and two transmission wheels. The transmission wheels are rotatably arranged on the working machine body for traveling the working machine body. When the transmission wheels are moved into the position-limiting slots, respectively, the mobile vacuum cleaner presses the parking plate by a gravity of the mobile vacuum cleaner through the two transmission wheels.

A beacon for a robotic cleaner may include a housing and an optical indicium having an optical pattern. The optical indicium may be coupled to the housing and be viewable by a camera of the robotic cleaner. After observing the optical indicium, the robotic cleaner may be caused to carry out an action associated with at least a portion of the optical pattern.

A cleaning robot system including a robot and a robot maintenance station. The robot includes a robot body, a drive system, a cleaning assembly, and a cleaning bin carried by the robot body and configured to receive debris agitated by the cleaning assembly. The robot maintenance station includes a station housing configured to receive the robot for maintenance. The station housing has an evacuation passageway exposed to a top portion of the received robot. The robot maintenance station also includes an air mover in pneumatic communication with the evacuation passageway and a collection bin carried by the station housing and in pneumatic communication with the evacuation passageway. The station housing and the robot body fluidly connect the evacuation passageway to the cleaning bin of the received robot. The air mover evacuates debris held in the robot cleaning bin to the collection bin through the evacuation passageway.