laser machining of structural ceramics: an integrated experimental & numerical approach for...
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Laser Machining of Structural Ceramics: An Integrated Experimental & Numerical Approach for Surface
FinishHitesh D. Vora and Narendra B. Dahotre
Laboratory for Laser Materials Processing & Synthesis, Materials Science and Engineering, University of North Texas, Denton, Texas, USABackground
Motivation
Numerical Study
Funding: National Science Foundation (CMMI 1010494)
Schematic of laser-material interaction
Conventional machining techniques (grinding)• Unacceptable tool wear & insufficient
accuracy • Mechanical or/and thermal damage• Lower material removal rate or
machining time• Higher operating costs
Potential solution: Laser Machining • Innovative and potential tool for bulk
material removal and shaping of structural ceramics
• Non-contact process - eliminates tool wear
• Efficient, reliable, cost effective solution to fabricate complex structures at large scales
Laser-Material Interaction
Current research aims at presenting the state of the art in the field of laser machining of alumina and emphasizes on experimental and computational approaches in understanding physical nature of the complex phenomena.
Need: Obtaining desired surface finish at much higher material removal rate
Solution: Better understanding of various physical phenomena (heat transfer & fluid flow) and its influence on the evolution of surface finish during laser machining of ceramics
Objective
All explained physical phenomena happened• within the small interval of time• very difficult to observed physically• Solution→ finite element
method
Experimental Study
• Laser power density in Gaussian distribution
Governing Equations
A COMSOL® multiphysics based two-step numerical model coupled with heat transfer and fluid flow was developed
2
2
2 2exp
4
.locx
DP
EAP
w
pg
• Recoil pressure (Pr) at the evaporating surface depends on the incident laser energy density and is given by the following equation
• Navier-Stokes equations was used to model the movement of the liquid under the action of the recoil pressure
Results & Discussions
Heat conduction
Surface melting
Surface Vaporization
Plume formation
Recoil pressure
Liquid pile-up
Rapid Solidification
Ongoing efforts include the extension of one-dimensional numerical model into two- and three-dimensional with inclusion of effects of multiple laser pulses on the resulting surface morphology during laser machining of alumina
Defense and space explorationThermal protection systems in exhaust cones, insulating tiles for space shuttle, ceramic coatings: engine components, and windshield glass of many airplanes
RefractoryHigh Temperature Strength, high wear resistance, high hardness and durability. Used in refractory products such as furnace liners, crucibles, structural insulation
Machining and fabrication
Excellent hardness & heat resistance properties ideal for drilling, shaping, grinding and
forming metal work pieces
Reference: Google imagesReference: Google images
Reference: Google imagesReference: Google images
a)prediction of solid, liquid & vapor interface by Level-set method,
b)prediction of crater and melt pool dimensions,
c) flow of molten material due to various boundary conditions,
d)prediction of surface profile after solidification
𝑃𝑟=( 𝑃𝑔) 1.69√𝐿𝑣 [ √( 𝑘 .𝑇 𝑠
𝑀 𝑣 .𝐿𝑣)
1+2.2( 𝑘 .𝑇 𝑠
𝑀 𝑣 .𝐿𝑣)2 ]𝑜𝑛𝑙𝑦 h𝑤 𝑒𝑛𝑇 ≥𝑇 𝑣
Test
Average Energy Density
Laser
pulses
Numerically
calculated Rt
Experimentally
measured Rt
standard deviation
Difference
# (J/m2) (1/s) (m) (m) (%)1 3.5x106 1 170.3 174.1 2.81 3.492 3.5x107 10 465.8 490 5.92 5.193 7.1x107 20 559.6 604 3.80 7.934 10.6x107 30 967.5 898 5.16 7.185 14.1x107 40 1030.96 1010 4.84 2.036 17.7x107 50 1870.06 1920 3.89 2.67
Experimentally measured and numerically predicted and surface
roughness
• Material lost due to evaporation causes an increase in crater depth
• Liquid expulsion created by the recoil pressure increase the pile-up height
• After a critical crater depth (260 m), recoil pressure was insufficient to eject the liquid material out of the crater
• Hence, liquid material solidified inside the crater wall leading to formation of typical tear drop shape topography
• Surface roughness increased with increasing pulse rate (1, 10, 20, 30, 40, and 50) or the increase in average laser energy density
• Process model can be used as a handy tool for the process engineers to configure the process variables to obtain the specified quality characteristics (surface finish & machining rates)
Acknowledgement
Path to multidimensional model
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