This module provides the fundamental aspects of fluid dynamics, dynamics and statistics associated with random processes and integrates them so that the students have a good understanding of hydrodynamics and seakeeping for a range of marine structures operating on or below the free water surface. There are two laboratories and one assignment (on seakeeping), which support understanding and application of the concepts taught.
Aims and Objectives
Knowledge and Understanding
Having successfully completed this module, you will be able to demonstrate knowledge and understanding of:
- The determination of loads acting on, and the fluid flow around, simple marine/ship-like structures.
- A classical fluid mechanics knowledge base established on fundamental principles.
- Model the seaway using deterministic and probabilistic approximations.
- Model the dynamic behaviour of rigid floating structures in waves.
- The basic unit of seaways (ie. the regular wave) and its definition with respect to a moving ship.
- Understand and apply the principles of dynamic response for basic systems.
- Construct suitable mathematical models to describe physical fluid-structure interactions and to calculate the fluid interaction characteristics
- Classical dynamics and their application to modelling the rigid body motions of floating structures.
- To review statistics and understand/apply probabilistic methods to waves and ship motions.
Basic elements of hydrodynamics:
- Linearization technique
- Flow velocity and acceleration
- Definition of inviscid flow and irrotational flow.
- Equation of continuity
- Definition of velocity potential.
- Definition of stream function for two-dimensional and special three-dimensional flows.
- Equation of motion, total derivative.
- Laplace Equation; Cauchy-Riemann conditions.
- Derivation of Bernoulli Equation for steady and unsteady flows.
- Mathematical operations of grad, div, curl, etc.
- Formulation of wave equation for finite depth with travelling waves.
- Hydrodynamic theory applied to towing tank and circulating water experiments
- Investigation of phase speed relationship.
- Standing waves - application in tanks.
- Dynamic pressure in waves.
- Mean rate of propagation of energy in waves.
- Group velocity.
- Shallow water wave theory.
- Velocity potential and stream function for source, sink, vortex and uniform stream.
- Combination flows - Rankine Oval, cylinders, etc.
- Multipoles - dipoles, quadropoles, images, etc.
- Added mass, virtual mass, added moment of inertia of simple ship shaped hulls.
- Lewis forms defining two-dimensional hull shapes.
Wave Experiment, where the wavemaker in the towing tank is employed to produce regular wave for the physical understanding of basic wave elements such as encounter frequency, dispersion relation, wave group and potential flow assumptions.
Systems with One and Two Degrees of Freedom :
- Summary of systems with one degree of freedom
- Two degrees of freedom systems in translation and/or rotation. Free motion and natural
- frequencies. Forced (sinusoidal) motion, resonance and motion amplitudes.
- Response of one degree of freedom systems to non-sinusoidal excitation.
- Response Amplitude Operator (RAO), Fourier series representation, discrete frequency spectra.
Wave Properties and Statistics
- Encounter frequency: relationship between ship speed, heading and wave frequency (or number) in head and following waves.
- Review of statistical methods; Probability density and distribution functions; Rayleigh and Gaussian distributions; Probability of exceedance; Mean, Mean Square and Significant values.
- Introduction to random processes. Irregular seaway; Fourier transform; Wave energy spectra; Definition of standard wave spectra (Pierson-Moskowitz, ITTC, ISSC); Directionality and
System with One and Multiple Degrees of Freedom in Waves:
- Equations of motion for heave, pitch and coupled heave and pitch in regular waves. Added mass, hydrodynamic damping and their evaluation. Generalisation to six degrees of freedom.
- Relationships between excitation and response. RAOs; Response spectra, RMS values. Absolute and relative motions.
- Equation of roll motion in regular waves. Roll control devices and active control.
Laboratory: Roll Stabilisation experiment, a ship model in the towing tank is used to understand and record the fundamental aspects of free and forced roll motion and the influence of hydrodynamic
roll damping and compare measurements to analytical predictions.
Seakeeping Assignment, where the students perform a seakeeping analysis to select the best of two proposed designs based on performance with reference to severe responses (slamming, deck
wetness and bow acceleration) in realistic waves – an application of what is learnt in lectures.
Learning and Teaching
Teaching and learning methods
Teaching methods include
- Lectures tutorials laboratory experiments
- Learning activities include
- Directed reading/independent learning
- Example sheets for problem solving exercises
- Report-writing (laboratory experiments; seakeeping assignment)
- Application of hydrodynamics and seakeeping knowledge through the seakeeping assignment
- Use of Ship Motions software for the seakeeping assignment
- Intermediate quizzes with feedback
|Wider reading or practice||15|
|Supervised time in studio/workshop||2|
|Completion of assessment task||29|
|Preparation for scheduled sessions||10|
|Total study time||150|
Resources & Reading list
Resources and reading list. Available on blackboard
This is how we’ll give you feedback as you are learning. It is not a formal test or exam.Quiz
This is how we’ll formally assess what you have learned in this module.
This is how we’ll assess you if you don’t meet the criteria to pass this module.
An internal repeat is where you take all of your modules again, including any you passed. An external repeat is where you only re-take the modules you failed.
Repeat type: Internal & External