A surface cleaning apparatus, such as a carpet extractor, includes a base and a fluid recovery system for drawing dirty cleaning fluid from a surface to be cleaned. The fluid recovery system includes a suction nozzle in fluid communication with a recovery chamber. The suction nozzle is mounted to the base for vertical movement with respect to the base and is biased into contact with the surface to be cleaned.

A surface cleaning apparatus, such as a carpet extractor, includes a base and a fluid recovery system for drawing dirty cleaning fluid from a surface to be cleaned. The fluid recovery system includes a suction nozzle in fluid communication with a recovery chamber. The suction nozzle is mounted to the base for vertical movement with respect to the base and is biased into contact with the surface to be cleaned.

This invention combines multiple tasks associated with carpet deep cleaning. It includes a self-propelled cleaner and guide system that will dispense, brush and retrieve a dry carpet cleaning pretreatment and powder across the surface of the carpet.

This invention combines multiple tasks associated with carpet deep cleaning. It includes a self-propelled cleaner and guide system that will dispense, brush and retrieve a dry carpet cleaning pretreatment and powder across the surface of the carpet.

A floor maintenance machine includes a clean water tank and a brush deck. A first and second fluid supply system place the clean water tank in fluid communication with outlet(s) at the brush deck. The first fluid supply system includes a first fluid supply line adapted to receive a soap or detergent therein supplied from a soap or detergent well. The second fluid supply system includes an ozone generator and a second fluid supply line adapted to receive injected ozone therein with the ozone being generated from the ozone generator.

The present disclosure relates generally to an apparatus for cleaning or otherwise treating a floor or ground surface. Devices provided herein include various features to enhance the efficiency and efficacy of cleaning operations. Such devices includes, but are not limited to, bearing protector devices, cord and cable management devices, and ergonomic features useful with ride-on floor treating machines.

The present disclosure relates generally to an apparatus for cleaning or otherwise treating a floor or ground surface. Devices provided herein include various features to enhance the efficiency and efficacy of cleaning operations. Such devices includes, but are not limited to, bearing protector devices, cord and cable management devices, and ergonomic features useful with ride-on floor treating machines.

A jet cleaning structure of a cleaning robot mainly comprising at least one jet port and one roller brush, wherein the jet port is disposed at a perimeter of a suction port at the bottom of the cleaning robot and is provided for ejecting air towards the underside of the suction port; the roller brush includes a shaft and a plurality of hard brush rods, wherein two ends of the shaft are disposed in a roller groove at the bottom of the cleaning robot, the plurality of hard brush rods is arranged in a straight or helical manner in equal parts on the shaft, when the cleaning robot is moving, the cleaning robot drives the shaft to rotate with respect to the moving direction of the cleaning robot so that the cleaning robot can use the plurality of hard brush rods to push away the fluff of the carpet and use the jet port to eject air to blow away the dust and foreign substance accumulated at the bottom of the fluff, thereby allowing the suction port disposed at the bottom of the cleaning robot to suck in the dust and foreign substance accumulated at the bottom of the fluff to the dust box and to effectively clean the carpet.

A jet cleaning structure of a cleaning robot mainly comprising at least one jet port and one roller brush, wherein the jet port is disposed at a perimeter of a suction port at the bottom of the cleaning robot and is provided for ejecting air towards the underside of the suction port; the roller brush includes a shaft and a plurality of hard brush rods, wherein two ends of the shaft are disposed in a roller groove at the bottom of the cleaning robot, the plurality of hard brush rods is arranged in a straight or helical manner in equal parts on the shaft, when the cleaning robot is moving, the cleaning robot drives the shaft to rotate with respect to the moving direction of the cleaning robot so that the cleaning robot can use the plurality of hard brush rods to push away the fluff of the carpet and use the jet port to eject air to blow away the dust and foreign substance accumulated at the bottom of the fluff, thereby allowing the suction port disposed at the bottom of the cleaning robot to suck in the dust and foreign substance accumulated at the bottom of the fluff to the dust box and to effectively clean the carpet.

A robotic cleaner system comprising a robotic vacuum cleaner configured for autonomous travel along a surface to be cleaned, and a stationary base station. The robotic vacuum cleaner comprises: a first brush arranged to rotate about a horizontal axis, a second brush arranged to rotate about a substantially vertical axis, and a control arrangement. The second brush is detachably connected to a main body of the robotic vacuum cleaner and the stationary base station is configured for receiving the second brush. The second brush is a side brush comprising bristles extending laterally outside a first brush width. The control arrangement is configured to disengage the second brush from the main body in the stationary base station when a surface portion of the surface to be cleaned is a carpeted surface portion.