This technology relates to system for clearing a sensor cover. The system may include a sprayer, a support, and a positioning device. The sprayer may be mounted to the support and direct a flow of fluid to the sensor cover. The positioning device may be configured to adjust the position of the sprayer on the support. The system may include a nozzle and the nozzle may be positioned to direct the flow of fluid to an area of the sensor cover. The system may include additional sprayers.

This technology relates to system for clearing a sensor cover. The system may include a sprayer, a support, and a positioning device. The sprayer may be mounted to the support and direct a flow of fluid to the sensor cover. The positioning device may be configured to adjust the position of the sprayer on the support. The system may include a nozzle and the nozzle may be positioned to direct the flow of fluid to an area of the sensor cover. The system may include additional sprayers.

A showerhead is disclosed including a first nozzle, a second nozzle, and a massage mode assembly in fluid communication with a fluid inlet, the first nozzle and the second nozzle. The massage mode assembly includes a turbine, a cam coupled to the turbine defining a dwell edge that extends between a leading corner and a follower corner, and a shutter movably coupled to the cam, where movement of the turbine causes the cam to drive shutter between a first position covering the first nozzle and opening the second nozzle and a second position opening the first nozzle and covering the second nozzle.

A showerhead with a massage engine is disclosed. The showerhead may include a housing defining a chamber in fluid communication with a fluid inlet and a massage mode assembly received within the chamber. The massage mode assembly may include a drive gear comprising a plurality of drive teeth, wherein the drive gear rotates due to fluid from the fluid inlet impacting the drive gear, and a driven gear comprising a plurality of driven teeth that mesh with the drive teeth of the drive gear, such that movement of the drive gear causes the driven gear to rotate, wherein the drive gear rotates faster than the driven gear rotates to selectively direct fluid from the fluid inlet to one or more nozzles.

An oscillating sprinkler includes a turbine operatively connected to a movable gear cage that is biased into either a first position or a second position using three torsion springs to drive rotation of a nozzle housing.

An oscillating sprinkler includes a turbine operatively connected to a movable gear cage that is biased into either a first position or a second position using three torsion springs to drive rotation of a nozzle housing.

A showerhead assembly is provided which includes a conduit, a gear train and oscillating nozzle chamber. The gear train includes a propeller, toothed pinion, and large toothed gear. Water flows from the conduit into an internal chamber within the showerhead housing. Specifically, water enters the propeller thereby causing it to rotate, the rotation of which causes the pinion to rotate, and consequently, the large gear to revolve. Additionally, a pin seated on the large gear engages with the pin slot located on the nozzle chamber and causes the chamber to pivot, thereby restricting chamber movement as the pin oscillates with rotation of the large gear. Further, the chamber's horizontal movement is hindered by two shoulder arms. As water exits the large gear, it travels through the left shoulder arm's central channel and into the oscillating chamber, whereby it expels through the nozzle outlet in a reciprocating spray pattern.

A showerhead assembly is provided which includes a conduit, a gear train and oscillating nozzle chamber. The gear train includes a propeller, toothed pinion, and large toothed gear. Water flows from the conduit into an internal chamber within the showerhead housing. Specifically, water enters the propeller thereby causing it to rotate, the rotation of which causes the pinion to rotate, and consequently, the large gear to revolve. Additionally, a pin seated on the large gear engages with the pin slot located on the nozzle chamber and causes the chamber to pivot, thereby restricting chamber movement as the pin oscillates with rotation of the large gear. Further, the chamber's horizontal movement is hindered by two shoulder arms. As water exits the large gear, it travels through the left shoulder arm's central channel and into the oscillating chamber, whereby it expels through the nozzle outlet in a reciprocating spray pattern.

The present disclosure discloses a water outlet mechanism comprising a water outlet body, a driving assembly, an eccentric cam, a swinging plate, and one or more water outlet nozzles. The water outlet body comprises a water inlet port, a water outlet port, and a water-passing cavity in communication with the water inlet port and the water outlet port. The driving assembly is disposed in the water-passing cavity. The eccentric cam is rotatably disposed in the water-passing cavity and is operatively coupled to the driving assembly. The swinging plate is swingingly disposed in the water-passing cavity and is operatively coupled to the eccentric cam. The one or more water outlet nozzles are swingingly disposed on the swinging plate and are configured to be driven by the swinging plate to perform reciprocating movement of swinging in a front-and-rear direction.

The present disclosure discloses a water outlet mechanism comprising a water outlet body, a driving assembly, an eccentric cam, a swinging plate, and one or more water outlet nozzles. The water outlet body comprises a water inlet port, a water outlet port, and a water-passing cavity in communication with the water inlet port and the water outlet port. The driving assembly is disposed in the water-passing cavity. The eccentric cam is rotatably disposed in the water-passing cavity and is operatively coupled to the driving assembly. The swinging plate is swingingly disposed in the water-passing cavity and is operatively coupled to the eccentric cam. The one or more water outlet nozzles are swingingly disposed on the swinging plate and are configured to be driven by the swinging plate to perform reciprocating movement of swinging in a front-and-rear direction.