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