Disclosed is a nozzle assembly for a sprayer, when a power of a sprayer is turned OFF, capable of not only minimizing an amount of liquid chemical remaining in a flow path at an inner side of a nozzle but also preventing backflow of the liquid chemical. The a nozzle assembly for a sprayer includes a nozzle assembly body molded in a ‘+’ shape; a nozzle assembled and installed in each of the plurality of nozzle assembly holes; a plurality of insert pieces fitting from an outside to an inside of four directions of a slide hole formed in a ‘+’ shape and forming a flow path for guiding a fluid flowing; and an end cap fixed and coupled to an outside in four directions of the slide hole in a state.

A micro-bubble spray head and a washing apparatus. The micro-bubble spray head includes an integrated spray tube and a micro-bubble bubbler fixed on the outlet end of the integrated spray tube; a throttling passage portion is formed in the integrated spray tube; a plurality of throttling passages parallel to each other and having a uniform cross section are formed in the throttling passage portion along a water stream direction, so that a plurality of water streams can be formed in the plurality of throttling passages parallel to each other and having the uniform cross section and are sprayed out from the outlets of the plurality of throttling passages parallel to each other and having the uniform cross section in an expansion manner, so as to form negative pressure near the outlets; a plurality of air inlets serving as air inlet passages are further provided on the integrated spray tube.

Disclosed is a nozzle assembly for a sprayer, when a power of a sprayer is turned OFF, capable of not only minimizing an amount of liquid chemical remaining in a flow path at an inner side of a nozzle but also preventing backflow of the liquid chemical. The a nozzle assembly for a sprayer includes a nozzle assembly body molded in a ‘+’ shape; a nozzle assembled and installed in each of the plurality of nozzle assembly holes; a plurality of insert pieces fitting from an outside to an inside of four directions of a slide hole formed in a ‘+’ shape and forming a flow path for guiding a fluid flowing; and an end cap fixed and coupled to an outside in four directions of the slide hole in a state.

A nozzle for atomizing and dispersing a discharge flow of a fluid, and a spacing plate for use in the nozzle is disclosed. The nozzle includes a bonnet, including an inlet port for receiving the fluid in the nozzle, and a first surface extending outward from the inlet port. The nozzle includes at least one deflector base, including a second surface arranged opposite to the first surface. At least one spacing plate is arranged between the first surface of the bonnet and the second surface of the deflector base. The spacing plate includes at least one gap extending through the spacing plate in its perpendicular direction (P) and extending from the outer periphery of the spacing plate to a distance (D) towards the inner section of the spacing plate. A discharge port is fluidly connected to the inlet port allowing the fluid to flow from the inlet port to surroundings of the nozzle. The discharge port is created between the first and the second surface and defined by the at least one gap of the spacing plate.

The present disclosure provides a spray device and a cleaning apparatus. The spray device includes an atomization structure, which is configured to atomize a cleaning liquid when the cleaning liquid is sprayed to form liquid droplets, and a jet structure, which is configured to spray a gas along a determined direction to cause the gas sprayed to collide with the liquid droplets to form atomized particles. The spray device provided by the present disclosure may increase cleaning uniformity and cleaning efficiency to improve cleaning process results, and may further reduce an impact force to the to-be-cleaned surface by the liquid droplets to a certain level. Thus, the damage to a surface pattern of a wafer may be reduced.

An apparatus and method directed to aspirated-type high-expansion foam generation having a nozzle manifold configured to receive a foam solution and at least one nozzle assembly. The generator includes a foam generator assembly disposed adjacent the nozzle manifold. The foam generator has a body portion having a first foam generating portion and a second foam generating portion that is connected to the first foam generating portion. The generator is configured with a main header of the nozzle manifold disposed orthogonal to at least one sub-header; less than six nozzle assemblies; a ratio of a diameter of an inlet of a respective nozzle to a distance from an inner wall surface of the header to the inlet of the respective nozzle is 0.8 or less; and a nozzle with a nozzle insert with a crossover path defined by a non-sharp transition member and a cone shaped tip.

A fluid dispenser head (T) including a spray wall (26) that is perforated with a network of holes (O) through which the fluid under pressure passes so as to be sprayed in small droplets; the dispenser head being characterized in that the network of holes (O) comprises at least two series of holes (O), with the holes (O) of a given series presenting holes that are substantially identical in size, and with the holes (O) of different series presenting holes that are different in size, such that one series of holes (O) generates a spray of small droplets with droplet sizes that define a first Gaussian distribution, while another series of holes (O) generates a spray of small droplets with droplet sizes that define a second Gaussian distribution that is offset relative to the first Gaussian distribution, thus producing a complex spray having at least two distinct Gaussian distributions.

An automatic adhesive spraying control system for progressive die of motor lamination core of a new energy vehicle according to the present disclosure includes a nozzle and a nozzle fixing plate, the nozzle fixing plate being provided with a mounting chamber, the nozzle being received in the mounting chamber, a top portion of the mounting chamber being a conical hole with an upper port being smaller than a lower port, a top cone of the nozzle being correspondingly inserted into the conical hole, a spring being arranged in the mounting chamber, two ends of the spring being respectively abutted against a bottom of the nozzle and a bottom side of the mounting chamber; wherein a side wall of the top cone of the nozzle is provided with an ejecting hole, the side wall of the top cone provided with the ejecting hole is attached to an inner side wall of the conical hole, a top of the nozzle extends out of the upper port of the conical hole, and an inlet orifice in communication with the mounting chamber is arranged at a bottom of the nozzle fixing plate; an adhesive supply device being connected to the inlet orifice via a pipe, an air pressure control system being mounted on the adhesive supply device, the air pressure control system supplying a push air pressure to an adhesive in the adhesive supply device and regulating a supplied push air pressure, such that a pressure ejected by the ejecting hole of the nozzle for ejecting the adhesive is controlled and regulated. This also facilitates adhesive application.

An electrostatic fluid delivery system is configured to deliver fluid, such as a disinfectant fluid, onto a surface by electrically charging the fluid and forming the fluid into a mist, fog, plume, or spray that can be directed onto a surface, such as a surface to be cleaned. The system atomizes the fluid using a high-pressure fluid stream and passes the fluid through an electrode of a nozzle assembly to charge droplets of the atomized fluid.

An electrostatic fluid delivery system is configured to deliver fluid, such as a disinfectant fluid, onto a surface by electrically charging the fluid and forming the fluid into a mist, fog, plume, or spray that can be directed onto a surface, such as a surface to be cleaned. The system atomizes the fluid using a high-pressure air stream and passes the fluid through an electrode inside a nozzle assembly to charge, such as negatively charge, droplets of the atomized fluid. The system uses a unique nozzle design that is configured to optimally atomize the fluid into various sized droplets.