FYP Thesis
Introduction
Background
Problem Statment
Objective
Chapter Outline
Introduction
Literature Review
Methodology
Result & Discussion
Conclusion
Rural Area
Shallow
Velocity
Designing
Renewable energy
Hydrokinetic
Hydrokinetic Turbine
Power used
Blade design
analysis
700- 1000 watt
Short Length
Airfoil
Power
High Cl airfoil
Graph
1.5 m/s
2m
Type
Horizontal
Vertical
Exist & limitation
Solar energy
Wind energy
Biomass
hydrokinetic
advantages
percentage use
Literature Review
Energy
Electrification in Malaysia
Use
Demand
Extraction Devices Type
HAHTs
VATs
Alternative turbine
HAHTs
Previous study
Pitch angle
Length
Blade design Consideration
Blade performance
Point
Formula
Power
Power Coefficient
Thrust
torque
Tsr value
Airfoil
Airfoil Performance
Formula for 2D airfoil
Type of airfoil
BEM Theory
BE theory
Momentum theory
Blade element eqn
Methodology ( Not final draft)
Approach
Numerical Simulation
Tools
BEM simulation
Q-blade
2d & 3d
Advantages
Outcome
parameter
power
Tsr
Torque
Thrust
Limitation
disavantages
compare w/ CFD
Procedure
flow chart
Description
Blade design
Airfoil design & analysis
simulation
Validation
Arzu
Raut
Big HAHTs
Small wind turbine
Compare result
Airfoil & parameter
Airfoil & parameter
graph
blade design
blade design
Conclude short
Motivation
explore renewable energy
continuance power
technology
rural area
technology
solar panel
hydropower
limitation of this technology(issues)
Alternative
small HAHts
advantages
disadvatages
type energy
wind
solar
hydrokinetic
biomass
issues
NON-renewable less
eco-freindly
explore worldwide
solar panel
turbine
biowaste