A linear oscillating water jet is capable of spraying in a linear oscillating fashion without deviating from a consistent linear path such that a resulting linear spray does not extend beyond a targeted area. Through the use of an internal turbine, energy from an incoming pressurized liquid is used to create rotational motion, which is subsequently converted into an oscillatory, back and forth linear motion by way of a rocker assembly that connects a nozzle assembly to the internal turbine. The oscillatory, linear motion of the rocker assembly is translated into a linear, back and forth rocking motion for the nozzle assembly.

A linear oscillating water jet is capable of spraying in a linear oscillating fashion without deviating from a consistent linear path such that a resulting linear spray does not extend beyond a targeted area. Through the use of an internal turbine, energy from an incoming pressurized liquid is used to create rotational motion, which is subsequently converted into an oscillatory, back and forth linear motion by way of a rocker assembly that connects a nozzle assembly to the internal turbine. The oscillatory, linear motion of the rocker assembly is translated into a linear, back and forth rocking motion for the nozzle assembly.

An oscillating sprinkler may include a main body, a water outlet tube, two moving members, a cover, and a c-shaped control ring. The main body has a connecting portion and a connecting tube respectively formed at two ends thereof, and the connecting tube is connected to a water source. The water outlet tube is cut in axial direction to form a water outlet portion, and a plurality of water outlet holes are separately formed thereon. A first elastic strip is installed in the interior of the water outlet tube, and a plurality of elastic nozzles are formed on the first elastic strip at positions corresponding to the water outlet holes.

An oscillating sprinkler may include a main body, a water outlet tube, two moving members, a cover, and a c-shaped control ring. The main body has a connecting portion and a connecting tube respectively formed at two ends thereof, and the connecting tube is connected to a water source. The water outlet tube is cut in axial direction to form a water outlet portion, and a plurality of water outlet holes are separately formed thereon. A first elastic strip is installed in the interior of the water outlet tube, and a plurality of elastic nozzles are formed on the first elastic strip at positions corresponding to the water outlet holes.

A cleaning system may be used with a heat exchanger having a core and a fan. The core may include a first core face and an oppositely disposed second core face. The cleaning system may include a plurality of wash nozzles arranged between the first core face and the fan of the heat exchanger. The cleaning system may be used while the heat exchanger is in operation, reducing the downtime of the heat exchanger. A method of retrofitting a heat exchanger with a cleaning system may include arranging a plurality of wash nozzles between the first core face and the fan of the heat exchanger. A method of cleaning a heat exchanger may include arranging a plurality of wash nozzles between the first core face and the fan, supplying a cleaning fluid to the plurality of nozzles, and initiating a cleaning cycle while the heat exchanger is in operation so that the fan assists in moving the cleaning fluid through the core and removing accumulated debris from the second core face.

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.

Described is a nozzle for spraying substances, in particular dispersions, emulsions or suspensions.

Described is a nozzle for spraying substances, in particular dispersions, emulsions or suspensions.

A fluidic component for generating a free jet includes a flow chamber that can be traversed by a fluid stream which enters the flow chamber through an inlet opening and exits from the flow chamber through an outlet opening and whose flow direction extends substantially parallel to the main direction of extension of the flow chamber. Within the flow chamber, a main flow channel and secondary flow channels are arranged. The cross-sectional profile of the main flow channel is divergent or sectionally divergent and sectionally convergent along the entire length of the main flow channel in the direction of the main direction of extension of the flow chamber.

A linear oscillating water jet is capable of spraying in a linear oscillating fashion without deviating from a consistent linear path such that a resulting linear spray does not extend beyond a targeted area. Through the use of an internal turbine, energy from an incoming pressurized liquid is used to create rotational motion, which is subsequently converted into an oscillatory, back and forth linear motion by way of a rocker assembly that connects a nozzle assembly to the internal turbine. The oscillatory, linear motion of the rocker assembly is translated into a linear, back and forth rocking motion for the nozzle assembly.