Ultrasonic Spray Coating Benefits:
Reduced material consumption and overspray by up to 80%
Highly controllable spray patterns for reliable, consistent results
Corrosion-resistant construction
Ultra-low flow rate capabilities
Low maintenance non-clogging design
Reduced downtime in critical manufacturing processes
High reliability with no moving parts
Ability to control atomized drop size by choice of nozzle frequency
Tight drop distribution allows for optimization to desired coating morphology
Seamless scalability from R&D to pilot line and high volume coating lines
Easily integrates with high volume production lines
Enables and enhances sustainable manufacturing practices with low waste and energy consumption
A better way to spray – ultrasonic coating technology has replaced conventional coating systems in a wide range of industrial and R&D applications, and enabled spray processes that would otherwise be impossible. Compared to many other coating systems, ultrasonic spray nozzles are more precise, more controllable, more repeatable, and more environmentally friendly.
The unpressurized, low-velocity spray is easily controlled and significantly reduces the amount of overspray since the drops settle on the substrate, rather than bouncing off it. This translates into substantial material savings and reduction in emissions into the environment.
The nozzles are inherently non-clogging, self-cleaning devices due to continuous ultrasonic vibrations and their relatively large orifice. ultrasonic spray nozzles are fabricated from titanium for long life and excellent acoustical properties. Visit How Ultrasonic Nozzles Work for more information about this unique spray technology.
Ultrasonic nozzles open up a broad range of new application possibilities. The nozzles are ideal, for example, when extremely low flow rates are required. And they offer unique benefits when spraying particles in suspension, keeping particles evenly suspended during the entire spray process through the ultrasonic action of the nozzle itself. This results in more uniform dispersion of

