Experimental investigation of free jets through supersonic nozzles

TL;DR

This study experimentally compares the performance of a novel parabolic supersonic nozzle with traditional conical nozzles, demonstrating comparable or improved axial density and jet profile for molecular jet applications.

Contribution

It introduces a parabolic nozzle design generated via the virtual source model and evaluates its performance against conical nozzles through experiments and simulations.

Findings

Parabolic nozzle performance is comparable or slightly better than conical nozzles.

Additive manufacturing with ABS is effective for nozzle fabrication.

Optimal opening angles can be determined for various conical nozzle lengths.

Abstract

In this paper, we report experimental investigation to improve the shape of a supersonic nozzle for rarefied flows to generate high axial density at extended distances from the nozzle. The reported work is significant for molecular jet/beam applications that require high center-line density and narrow jet profile. We investigate a parabolic nozzle whose profile is generated using the virtual source model of free expansion and compare its performance with a set of conical nozzles having different cone angles using simulations as well as experiments. All nozzles are made by additive manufacturing using ABS and performance is found to be satisfactory. Axial density and lateral spread of the jets are measured using a pitot tube assembly. The accuracy and operational limit of the pitot tube for rarefied flow is quantified by using established mathematical and empirical models for a sonic nozzle. The study demonstrates that the performance of the parabolic nozzle is comparable or slightly better as compared to conical counterparts. Moreover, the parabolic profile can be used for optimizing the opening angle for conical nozzles of various lengths.