Oscillatory incompressible fluid flow with a free surface occurs in an inkjet print head. Due to complex physical fluid behavior, numerical simulations have been a common approach to characterize the pressure and velocity development in time and space. However, the cost of a numerical approach is high in terms of computational time such that approximate analytic approaches have been developed. In this paper, an approximate analytic solution for a tapered nozzle section is described with a proper downstream boundary condition and the physical behavior of the meniscus deformation is modeled with a simple “window” theory.

Issue Section:
Technical Papers
Keywords:
fluid oscillations, ink jet printers, pipe flow, flow simulation, nozzles
Topics:
Boundary-value problems, Flow (Dynamics), Nozzles, Pressure, Deformation, Computer simulation, Computation
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