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A multiobjective parameter study of two-phase flow channel design
Nicholas A. Evich
, Nicholas R. Larimer
,
Mary I. Frecker
, Matthew J. Rau
Mechanical Engineering
Research output
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Chapter in Book/Report/Conference proceeding
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Dive into the research topics of 'A multiobjective parameter study of two-phase flow channel design'. Together they form a unique fingerprint.
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Keyphrases
Parameter Study
100%
Two-phase Flow
100%
Heat Transfer
75%
Manufacturing Methods
50%
Flow Transferring
50%
Operating Conditions
25%
Degrees of Freedom
25%
Design Tools
25%
Heat Transfer Coefficient
25%
Heat Flux
25%
Heat Input
25%
Pressure Drop
25%
High-temperature Heat Transfer
25%
Flow Channel
25%
Mass Flow Rate
25%
Cross-sectional Area
25%
Single Channel
25%
Complex Geometry
25%
Flow System
25%
New Design Approach
25%
Design Objectives
25%
Heat Transfer Correlation
25%
Two-phase Heat Transfer
25%
Traditional Manufacturing
25%
Orientation Angle
25%
Inlet Channel
25%
Hydraulic Diameter
25%
Circular Cross-section
25%
Liquid Mass
25%
Feasible Design
25%
Design Freedom
25%
Channel Orientation
25%
Traditional Architecture
25%
Channel Design
25%
New Manufacturing
25%
Straight Channel
25%
Homogeneous Equilibrium Model
25%
Flow Length
25%
Engineering
Flow Channel
100%
Two-Phase Flow
100%
Manufacturing Technique
75%
Design Method
50%
Degree of Freedom
25%
Heat Transfer Coefficient
25%
Pressure Drop
25%
Constrains
25%
Mass Flowrate
25%
Single Channel
25%
Flow System
25%
Operational Condition
25%
Advanced Manufacturing
25%
Design Objective
25%
Hydraulic Diameter
25%
Circular Cross Section
25%
Feasible Design
25%
Thermal Fluid
25%
Fluid System
25%
Input Heat
25%
Design Tool
25%
Heat Flux
25%
Equilibrium Model
25%
Flow Length
25%
Two Phase Flow Pressure Drop
25%