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PARK, SEONG JIN (박성진)

Dept of Mechanical Engineering(기계공학과)

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COMPOSITES:14||BEHAVIOR:14||SIMULATION:12||POWDER:10||FLOW:10||MODEL:10||MECHANICALPROPERTIES:9||powder injection molding:8||EVOLUTION:8||Powder metallurgy:6||BINDER REMOVAL:6||CONSTITUTIVE MODEL:6||ORGANIC VEHICLE:6||GRAINGROWTH:6||TUNGSTEN HEAVY ALLOYS:6||FEEDSTOCK:6||Powder injection molding:6||RHEOLOGY:6||RESIDUAL CARBON:6||EMBEDDEDATOM POTENTIALS:6||Powder injection moulding:6||powder injection moulding:6||CERAMICS:6||DENSIFICATION:6||MOLYBDENUM:6||SUSPENSIONS:6||DESIGN:6||SILICONCARBIDE:4||Taguchi robust design:4||ALLOY:4||master sintering curve:4||TITANIUM:4||METAL MOLDINGS:4||finite element method:4||INJECTIONMOLDED CERAMICS:4||NUMERICALSIMULATION:4||IMPURITIES:4||PURITY NIOBIUM:4||PRESSURE:4||FABRICATION:4||MOLDED PARTS:4||POLYPROPYLENE:4||Mechanical properties:4||DUCTILITY:4||HCP METALS:4||MASTER SINTERING CURVE:4||HfB220SiC:4||SPS:4||GRAVITY:4||CREEP:4||COMPACTS:4||Computer simulation:4||Activation energy:4||Solvent debinding:4||FIBER ORIENTATION:4||Densification:4||rheology:4||Sintering:4||CENTERGATED DISK:4||Modeling:4||activation energy:4||VISCOSITY:4||NANOCRYSTALLINE:4||OPTIMIZATION:4||MICRO COMPONENTS:4||STRENGTH:4||AUGMENTEDWAVE METHOD:4||Compaction:4||MOLECULARDYNAMICS:3||Magnetic PIM:2||PARTICULATEREINFORCED COMPOSITES:2||Rocket nozzle:2||STAINLESSSTEEL POWDER:2||METAL:2||MICROSTRUCTURE:2||PARTICLESIZE:2||NAVIERSTOKES EQUATIONS:2||Master debinding curves:2||KINETICS:2||powder injection molding (PIM):2||Defects:2||POLY(VINYL BUTYRAL):2||NACRE:2||suspension:2||viscoelasticity:2||Composite powder:2||Al6061 powder:2||MG:2||DEGRADATION:2||STIFFNESS:2||BOVIDS:2||SINTERING DIAGRAMS:2||Mechanical alloying:2||Powder:2||Steel:2||Gasassisted injection molding:2||Tungsten:2||Al6061 powder:2||Composites:2||PROCESS OPTIMALDESIGN:2||backlight unit (BLU):2||SHAPE DISTORTION:2||powder metallurgy:2||mixing condition:2||Injection molding:2||DISTORTION:2||NI3 PCT FE:2||HEATCAPACITY:2||MATRIX:2||RHENIUM ALLOYS:2||OXIDATION:2||Rheology:2||Packing fraction:2||Silicon carbide:2||SINTERING BEHAVIOR:2||THERMALCONDUCTIVITY:2||Stress and strains during thermal debinding:2||THERMODYNAMICS:2||plastic injection molding:2||metal injection molding:2||hot embossing:2||ALLOY POWDERS:2||MODULATION:2||ELEMENTMETHOD:2||NANOCRYSTALLINE FEAL:2||DECOMPOSITION:2||CURVE:2||WEAR:2||Gasassisted powder injection molding:2||NANOPARTICLES:2||SILICON:2||Particulate materials:2||light guide:2||liquid phase sintering:2||sensitivity analysis:2||shear viscosity:2||optimum filling time and PIM parameters:2||FILLING PROCESS:2||THERMALDECOMPOSITION:2||CATALYTIC PYROLYSIS:2||SLPS:2||filling stage:2||WALL SLIP:2||GOLD PARTICLES:2||Shear viscosity:2||ALUMINUM NITRIDE:2||FILLED POLYMER:2||HAFNIUM DIBORIDE:2||SINTERING CURVE:2||Aluminum nitride:2||EXPANSION:2||yield stress:2||ORTHODONTIC BRACKETS:2||Residual carbon:2||Carapace:2||STROMBUSGIGAS:2||DYNAMICMECHANICAL RESPONSE:2||NANOCOMPOSITE:2||particle orientation:2||squeezing flow:2||ALUMINUMALLOYS:2||Horn:2||Temperature:2||METALMATRIX COMPOSITES:2||DAMPING BEHAVIOR:2||SS316L:2||Grain boundary misalignment:2||SIZE RANGE:2||AL/SIC INTERFACE:2||Microsystem components:2||Optimisation:2||Adjoint variable method (AVM):2||tungsten heavy alloy:2||computer simulation:2||niobium:2||die compaction:2||NI:2||powder injection molding of niobium:2||optimisation:2||HARD MATERIALS:2||NANOCRYSTALLINE WC:2||DENSIFICATION BEHAVIOR:2||Powders/binders feedstocks:2||GAS:2||WNiCu alloy:2||Premixed powder:2||Master sintering curve (MSC):2||WCCO ALLOYS:2||CARBIDECOBALT SYSTEM:2||COMPUTERSIMULATION:2||SHORTCIRCUIT:2||NANOCOMPOSITES:2||HIGHTEMPERATURE CERAMICS:2||Metals and alloys:2||WCU:2||magnetorheology (MR):2||oscillatory shear test:2||MAGNETORHEOLOGICAL FLUIDS:2||Thermal debinding:2||POLYMER BINDER BURNOUT:2||taguchi method:2||Die wear:2||CHEMISTRY:2||CONCENTRATED SUSPENSIONS:2||Stearic acid:2||degradation kinetics:2||Viscoelastic behaviour:2||FOAMED ALUMINUM:2||Aluminium alloy powder:2||Atomistic simulation:2||MATRIX COMPOSITES:2||Design sensitivity:2||FINITEELEMENTMETHOD:2||direct surface forming (DSF):2||modeling:2||thermal debinding:2||sintering of Nb:2||ALUMINA COMPACTS:2||STEEL POWDER:2||PIM:2||Delubrication:2||CONCENTRATED SUSPENSION:2||mould filling simulation:2||Xray line broadening:2||scanning electron microscopy:2||magnetic coercivity:2||Iron and steel powders:2||THERMALEXPANSION BEHAVIOR:2||Spark plasma sintering:2||Wicking:2||COMPACTION:2||DEFORMATION:2||EXOSKELETON:2||MICROSTRUCTURES:2||Keratin:2||COOLING SYSTEM:2||FE40AL ALLOY:2||Wear work:2||Surface roughness:2||Tool wear:2||Silicon rubber:2||Iron alloy powder:2||Gas penetration:2||Liquid phase sintering:2||Alloying elements:2||PARTICLES:2||Mould filling simulation:2||PREFORM DESIGN:2||RESIDUALSTRESSES:2||FORMULATION:2||thinfilmtransistor liquidcrystallinedisplay (TFTLCD):2||MICROFABRICATION:2||dilatometer:2||Master decomposition curve:2||KINETICMODEL:2||sintering:2||SIMULATIONS:2||ALUMINA:2||Rheological behavior:2||PRESSED SILICONNITRIDE:2||MICROSTRUCTURAL EVOLUTION:2||VEHICLE:2||SYSTEM:2||Rheological modeling:2||Rhenium:2||TUNGSTEN:2||Bimodal mixtures:2||SHEAR VISCOSITY:2||In situ strength:2||Master decomposition curves:2||CERAMIC INJECTION MOLDINGS:2||ceramic injection molding:2||PARTICLE MIGRATION:2||ATPERCENT AL:2||PALLADIUM:2||SILVER:2||Tool material:2||Modelling:2||ALUMINUMALLOY POWDERS:2||Residual wall thickness:2||Boron:2||Neck growth:2||ATMOSPHERE:2||Finite element method (FEM):2||FORMULATIONS:2||POLYMERS:2||solvent debinding:2||Nb:2||molybdenum:2||Nb powder and feedstock:2||rheological properties of niobium:2||moldability index:2||critical solids loading:2||COPOLYMERS:2||POINT DEPRESSION:2||CLUSTERS:2||Slip phenomena:2||Yield stress:2||SLIP:2||MAGNETICPROPERTIES:2||CEMENTED CARBIDES:2||GROWTH:2||TOUGHNESS:2||Mold filling:2||DIHEDRAL ANGLE MEASUREMENT:2||COMPUTATIONAL MODELS:2||CELLS:2||thermal properties:2||CONDUCTIVITY:2||AID:2||Diffusion:2||STATE:2||Taguchi analysis:2||Field assisted sintering (FAST):2||Densify ultra high temperature ceramics:2||ZRB2ZRCSIC COMPOSITES:2||MODELS:2||Distortion:2||Cracks:2||Microwave:2||POROSITY DEVELOPMENT:2||Turtle shell:2||Simulation:2||ORIENTATION:2||THERMOPLASTICS:2||Taguchi method:2||FeAl intermetallic:2||POLYANILINE:2||palladium/polycarbonate nanocomposites:2||GOLD NANOPARTICLES:2||MICROSCOPY:2||Frequency effects:2||Sinter modelling:2||Master sintering curve:2||Die compaction:2||POROUS METALS:2||CYCLIC LOADING DILATOMETRY:2||numerical analysis:2||DENSITY POLYETHYLENE:2||NANOCALORIMETRIC MEASUREMENTS:2||nanograined WCCo:2||Homogenization:2||Prealloyed powder:2||moldfilling simulations:2||ELASTIC PROPERTIES:2||Field assisted sintering:2||Maser sintering curve:2||COMPOSITE:2||Thermal analysis:2||DECOMPOSITION CURVE:2||Nanoparticles:2||ZIRCONIA NANOPARTICLES:2||PART I:2||steady shear test:2||Bubble formation criteria:2||Microstructure:2||MASTER DECOMPOSITION CURVE:2||Compression test:2||TIBIAL CORTICAL BONE:2||STRESS:2||ROBUST DESIGN METHOD:2||Aluminium:2||PARTICLE:2||Stressstate dependence:2||Structureproperty relations:2||Tribology:2||Rapid prototyping:2||Nanoscale:2||Differential scanning calorimeter:2||INTERFACIAL REACTION:2||ALGORITHMS:2||distortion:2||mould filling:2||master decomposition curve:2||SINTERING MOLYBDENUM:2||SHRINKAGE:2||CONDENSEDSOLVENT:2||Binder pyrolysis:2||MOLDINGS:2||TEMPERATURE:2||Integrated analysis:2||microsystem components:2||grain size measurement:2||ALLOYS:2||CERAMIC COMPONENTS:2||REARRANGEMENT DENSIFICATION:2||LOADING CONDITIONS:2||

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