Abstract
This paper focuses on the investigation of a multiphase flow of water, air, and abrasive particles inside and at the outlet of the abrasive head with the help of computational fluid dynamics calculations and measurements. A standard abrasive head with a water nozzle hole diameter of 0.33 mm (0.013”) and an abrasive nozzle cylindrical hole diameter of 1.02 mm (0.04”) were used for numerical modelling and practical testing. The computed tomography provided an exact 3D geometrical model of the cutting head that was used for the creation of the model. Velocity fields of abrasive particles at the outlet of the abrasive head were measured and analysed using particle tracking velocimetry and, consequently, compared with the calculated results. The calculation model took the distribution of the abrasive particle diameters with the help of the Rosin-Rammler function in intervals of diameters from 150 to 400 mm. In the present study, four levels of water pressure (105, 194, 302, 406 MPa) and four levels of abrasive mass flow rate (100, 200, 300, 400 kg/min) were combined. The values of water pressures and hydraulic powers measured at the abrasive head inlet were used as boundary conditions for numerical modelling. The hydraulic characteristics of the water jet were created from the measured and calculated data. The calculated pressure distribution in the cylindrical part of the abrasive nozzle was compared with studies by other authors. The details of the experiments and calculations are presented in this paper.
Highlights
Abrasive water jet (AWJ) is a progressive technology due to its various advantages.It is currently applied in the manufacturing industry, especially for processing difficultto-machine materials such as ceramics, composites, and alloys [1,2]
The method using AWJs has been successfully applied for the determination of the erosion resistance of concretes treated with a solution of modified lithium silicates [5]
Liu et al [10,11] developed computational fluid dynamics (CFD) models for three-phase flow at the nozzle outlet based on 2D axisymmetric geometry, significantly simplifying the mixing chamber’s inner shape
Summary
Abrasive water jet (AWJ) is a progressive technology due to its various advantages.It is currently applied in the manufacturing industry, especially for processing difficultto-machine materials such as ceramics, composites, and alloys [1,2]. Calculated data of an inaccurate model were adjusted and Materials 2021, 14, 3919 verified using experimental methods of particle velocity measurement at the outlet of the abrasive nozzle, i.e., the PTV and laser-induced fluorescence (LIF). A recent study published by Haghbin et al [22] using a modified rotating dual-disc anemometer provided very good agreement with the measured results of the existing analytical models of abrasive particle velocity. It is obvious from the previous investigations that flow modelling during AWJ generation and particle velocities at the nozzle outlet were studied. The methods used are described in more detail
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