Presentation is loading. Please wait.

Presentation is loading. Please wait.

Mathematical modelling in the field of kites Calculation of kites strength, shape and aerodynamic coefficients  Material Science, Solid mechanics, Aerodynamics,

Published byAbigayle Cooper Modified over 8 years ago

Similar presentations

Presentation on theme: "Mathematical modelling in the field of kites Calculation of kites strength, shape and aerodynamic coefficients  Material Science, Solid mechanics, Aerodynamics,"— Presentation transcript:

1 Mathematical modelling in the field of kites Calculation of kites strength, shape and aerodynamic coefficients  Material Science, Solid mechanics, Aerodynamics, Aeroelasticity Finding kites trajectory, speed and attitude  Multi-body dynamics Laddermill control  Stability, optimization and optimal control Problems of aerodynamics  Airflow around the kite  Finding the aerodynamic coefficients Problems of aeroelasticity  Finding the shape of the kite under air load  Finding the aerodynamic coefficients Problems of solid mechanics  Prediction of fatigue and failure of kite materials and structure  Prediction of life cycle length

2 Mathematical modelling in the field of kites

3

4

5 What’s next? Courtesy of Rensselaer Polytechnic Institute Courtesy of University of California in Irwing Courtesy of Ecole Polytechnique de Montréal

6 Step 32 Step 155 Step 806 The pictures of the airflow around 6*3 pt plate in a 30*30 pt region Mathematical modelling in the field of kites

7

8 Initial conditions: and. Here: Equations of motion: Mathematical modelling in the field of kites

9 Stability of energy production here w is wind speed and E is energy production

10 Flight optimization T  a Δ Δ a 1. Creating the table of tests 2. Determining Pareto-set 3. Choosing constraints on objectives.

11 Choice of test points Equidistant grid LP τ : all coordinates of all points are different

12 Mathematical modelling in the field of kites Calculation of kites strength, shape and aerodynamic coefficients  Material Science, Solid mechanics, Aerodynamics, Aeroelasticity Finding kites trajectory, speed and attitude  Multi-body dynamics Laddermill control  Stability, optimization and optimal control Problems of aerodynamics  Airflow around the kite  Finding the aerodynamic coefficients Problems of aeroelasticity  Finding the shape of the kite under air load  Finding the aerodynamic coefficients Problems of solid mechanics  Prediction of fatigue and failure of kite materials and structure  Prediction of life cycle length

Download ppt "Mathematical modelling in the field of kites Calculation of kites strength, shape and aerodynamic coefficients  Material Science, Solid mechanics, Aerodynamics,"

Similar presentations

A SEMINAR ON IMPACT OF AERODYNAMICS IN DESIGN

A SEMINAR ON IMPACT OF AERODYNAMICS IN DESIGN
These describe matter. Starts with a “p”

These describe matter. Starts with a “p”
Heat Transfer with Change of Phase in Continuous Casting Ernesto Gutierrez-Miravete Rensselaer at Hartford ANSYS Users Group Meeting September 28, 2010.

Heat Transfer with Change of Phase in Continuous Casting Ernesto Gutierrez-Miravete Rensselaer at Hartford ANSYS Users Group Meeting September 28, 2010.
Power Flow Active Control of Aeroelastic Flutter for a Nonlinear Airfoil with Flap N.Zhao 1,2, Supervisors – Dr. Y.P.Xiong 1 and Prof. D.Q.Cao 2 1 School.

Power Flow Active Control of Aeroelastic Flutter for a Nonlinear Airfoil with Flap N.Zhao 1,2, Supervisors – Dr. Y.P.Xiong 1 and Prof. D.Q.Cao 2 1 School.
Chapter 13 Buckling of Columns

Chapter 13 Buckling of Columns
VISCOUS CFD ANALYSIS OF GENERIC MISSILE WITH GRID FINS By Swapnil. D

VISCOUS CFD ANALYSIS OF GENERIC MISSILE WITH GRID FINS By Swapnil. D
AeroAcoustics & Noise Control Laboratory, Seoul National University

AeroAcoustics & Noise Control Laboratory, Seoul National University
DO NOW #21.5 On a separate sheet of paper, use the ladder method and convert the following: 1.256 m = ______ cm 2.97.25 cm = ______ mm 3.8.26 kL = ______.

DO NOW #21.5 On a separate sheet of paper, use the ladder method and convert the following: m = ______ cm cm = ______ mm kL = ______.
Choose the right picture. 1 2 3 4 5 6 7 8.

Choose the right picture
Rocket Aerodynamics and Stability

Rocket Aerodynamics and Stability
Rocketry 101 Jeremy Young American Institute of Aeronautics and Astronautics at UCF.

Rocketry 101 Jeremy Young American Institute of Aeronautics and Astronautics at UCF.
Development of Guidance and Control System for Parafoil-Payload System VVR Subbarao, Sc ‘C’ Flight Mechanics & Control Engineering ADE.

Development of Guidance and Control System for Parafoil-Payload System VVR Subbarao, Sc ‘C’ Flight Mechanics & Control Engineering ADE.
ICME and Multiscale Modeling

ICME and Multiscale Modeling
ENGR 225 Section 1.1 -1.2.

ENGR 225 Section
PROJECTS WITH POTENTIAL FUNDING

PROJECTS WITH POTENTIAL FUNDING
Starter Activity Write the equation of a circle with a center of

Starter Activity Write the equation of a circle with a center of
Kite Flight Dynamics Sean Ganley and Z! Eskeets Calculus 114.

Kite Flight Dynamics Sean Ganley and Z! Eskeets Calculus 114.
Next: Wind Turbine Rotors Goal ?. Question 1  Divergent thinking consists of A) Selection of unique answer B) Brainstorming many ideas.

Next: Wind Turbine Rotors Goal ?. Question 1  Divergent thinking consists of A) Selection of unique answer B) Brainstorming many ideas.
THE INVENTION OF THE AIRPLANE 1897 - 1901 ORVILLE WILBUR Part 1: Background & Failures.

THE INVENTION OF THE AIRPLANE ORVILLE WILBUR Part 1: Background & Failures.
1 1 The Laddermill - Design, Building & Testing Bas Lansdorp Richard Ruiterkamp Background Kite control mechanism Groundstation Electronics Testing.

1 1 The Laddermill - Design, Building & Testing Bas Lansdorp Richard Ruiterkamp Background Kite control mechanism Groundstation Electronics Testing.

Similar presentations

Ads by Google