scholarly journals Experimental analysis and numerical modeling of particle embedment and fracture in the solid particle erosion of ductile materials

2021 ◽  
Author(s):  
Vahid Hadavi
Keyword(s):  
Numerical Modeling ◽  
Kinetic Energy ◽  
Solid Particle ◽  
Process Parameters ◽  
Three Dimensional ◽  
Pulsed Laser ◽  
Particle Orientation ◽  
Solid Particle Erosion ◽  
Particle Erosion ◽  
Particle Fracture

Embedment and fracture of abrasives are two often neglected important phenomena that can affect material removal occurring in industrial processes that involve high speed impact of particles on relatively ductile targets. This thesis proposes new methodologies to predict the likelihood of particle embedment and fracture for a typical solid particle erosion application. Double-pulsed laser shadowgraphy was used to measure the instantaneous orientation of angular 89-363 μm SiC particles within a micro-abrasive jet, in order to assess whether their orientation affected the propensity for particle embedment. A tendency for particles to orient with the jet axis was measured and successfully modelled (<9% error), with larger abrasives more likely to orient. The measured instantaneous orientation of particles was used to generate a three-dimensional coupled finite element and smoothed particle hydrodynamics model capable of simulating the particle embedment. Use of various combinations of process parameters yielded embedment predictions that agreed with measured ones with, at most, a 16% error. Increases in particle size, orientation angle, and velocity were found to enhance the propensity for embedment. Double-pulsed laser shadowgraphy was used to record the impact and fracture of abrasives upon impact. A numerical model that utilized an Element Free Galerkin (EFG) technique with a novel scheme for generating realistic three-dimensional particle geometries was used to simulate the particle fracture. For a wide variety of process parameters, the numerical predictions of particle average size, roundness and rebound velocity agreed with the corresponding measurements to within 10%, at most. The propensity for particle fracture was found to depend on the magnitude of particle kinetic energy perpendicular to the target. It was confirmed that at the same incident velocity, larger particles were more likely to fracture. However, for the same kinetic energy, smaller particles were more likely to fracture. To the best knowledge of the author, this thesis is the first to report measurements of particle orientation and particle fracture in abrasive jets, and the first to develop numerical modeling of particle fracture and embedment. The results have important implications for erosion testing and abrasive jet machining operations.

scholarly journals Experimental analysis and numerical modeling of particle embedment and fracture in the solid particle erosion of ductile materials

2021 ◽  
Author(s):  
Vahid Hadavi
Keyword(s):  
Numerical Modeling ◽  
Kinetic Energy ◽  
Solid Particle ◽  
Process Parameters ◽  
Three Dimensional ◽  
Pulsed Laser ◽  
Particle Orientation ◽  
Solid Particle Erosion ◽  
Particle Erosion ◽  
Particle Fracture

Embedment and fracture of abrasives are two often neglected important phenomena that can affect material removal occurring in industrial processes that involve high speed impact of particles on relatively ductile targets. This thesis proposes new methodologies to predict the likelihood of particle embedment and fracture for a typical solid particle erosion application. Double-pulsed laser shadowgraphy was used to measure the instantaneous orientation of angular 89-363 μm SiC particles within a micro-abrasive jet, in order to assess whether their orientation affected the propensity for particle embedment. A tendency for particles to orient with the jet axis was measured and successfully modelled (<9% error), with larger abrasives more likely to orient. The measured instantaneous orientation of particles was used to generate a three-dimensional coupled finite element and smoothed particle hydrodynamics model capable of simulating the particle embedment. Use of various combinations of process parameters yielded embedment predictions that agreed with measured ones with, at most, a 16% error. Increases in particle size, orientation angle, and velocity were found to enhance the propensity for embedment. Double-pulsed laser shadowgraphy was used to record the impact and fracture of abrasives upon impact. A numerical model that utilized an Element Free Galerkin (EFG) technique with a novel scheme for generating realistic three-dimensional particle geometries was used to simulate the particle fracture. For a wide variety of process parameters, the numerical predictions of particle average size, roundness and rebound velocity agreed with the corresponding measurements to within 10%, at most. The propensity for particle fracture was found to depend on the magnitude of particle kinetic energy perpendicular to the target. It was confirmed that at the same incident velocity, larger particles were more likely to fracture. However, for the same kinetic energy, smaller particles were more likely to fracture. To the best knowledge of the author, this thesis is the first to report measurements of particle orientation and particle fracture in abrasive jets, and the first to develop numerical modeling of particle fracture and embedment. The results have important implications for erosion testing and abrasive jet machining operations.

scholarly journals Assessment of Remaining Life of a Control Stage Blade With Solid Particle Erosion Damage

1993 ◽  
Author(s):  
Tony C.-T. Lam ◽  
Thomas H. McCloskey ◽  
Robert P. Dewey ◽  
Paul Wawrzynek
Keyword(s):  
Solid Particle ◽  
Structural Integrity ◽  
Service Failure ◽  
Three Dimensional ◽  
Solid Particle Erosion ◽  
Remaining Life ◽  
Particle Erosion ◽  
Erosion Damage ◽  
Mechanics Model ◽  
Control Stage

Unscheduled replacement of HP control stage blades due to solid particle erosion can be avoided if the structural integrity of the eroded blade has not been compromised, and the risk of an in-service failure is shown to be minimal. An analytical approach is presented which was used to evaluate whether blades with SPE damage could remain in service until the next convenient outage, in order to provide the plant engineers with specifications to assist them in determining the need for replacement based on further observed erosion damage. A three-dimensional fracture mechanics model was applied to study the propagation of cracks caused by erosion, and to assess when rupture was likely to occur. The results of the study are presented as a model for plant operators to use in scheduling the repair or replacement of HP blades.

scholarly journals Solid Particle Erosion of a Limestone Target Surface under Controlled Conditions

2020 ◽  
Vol 2020 ◽  
pp. 1-8
Author(s):  
Anna Laura Sanna ◽  
Giorgio Pia ◽  
Francesco Delogu
Keyword(s):  
Solid Particle ◽  
Material Removal ◽  
Three Dimensional ◽  
Target Surface ◽  
Solid Particle Erosion ◽  
Particle Erosion ◽  
Experimental Conditions ◽  
A Value ◽  
The One ◽  
Experimental Findings

This work focuses on the erodent capability of yttria-stabilized zirconia beads impacting on a limestone target surface. The target surface was used as the cap of a hardened steel vial clamped on a SPEX Mixer/Mill 8000. The vial three-dimensional swing results in repeated bead impacts that cause the material removal from the target surface. The mass loss varies linearly with the number of beads, which allowed estimating the mass lost per bead per impact. It amounts approximately to 70 ng, a value that compares fairly well with the one of about 80 ng estimated from the volume of the indents left on the target surface by individual impacts. Experimental findings indicate that the methodology developed can be reliably utilized to investigate solid particle erosion under highly reproducible and controllable experimental conditions.

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