Elastic nozzles could create more stable liquid jets
Liquid jets are found in an extensive array of applications: including cleaning, cutting, inkjet printing, and drug delivery in medicine. Across these different scenarios, it is often crucial for users to control the distance at which these jets break up, allowing them to carefully adjust the frequency and sizes of the resulting drops as they hit their targets. This length is tied to several different factors: including surface tension, liquid viscosity, and jet velocity. Currently, methods for controlling the breakup length include mixing the jet with a flowing gas, altering the nozzle’s geometry, and manipulating the jet after leaving the nozzle.
To assess the influence of deforming nozzles, Dickerson’s team constructed new equations to account for the interconnection between the flow of liquid and the elastic nozzle’s dilation. They then tested the accuracy of their mathematics using a series of simple nozzles – where a 0.5 mm hole was punched into different elastic membranes, each with a different stiffness. As they squirted liquid through these nozzles, the researchers found that the softest, most deformable materials provided the most stable jets across a wide range of flow rates. Their results provide valuable insights into how the stability of liquid jets could be improved – ultimately enabling their users to hit their targets more accurately.