ENVR E9Z09 - Ocean Energy

Module Details

Module Code: ENVR E9Z09
Full Title: Ocean Energy
Valid From:: Semester 1 - 2019/20 ( June 2019 )
Language of Instruction: 
Duration: 1 Semester
Credits:: 7.5
Module Owner:: Thomas Kelly
Departments: Unknown
Module Description: an advanced study of the theory and practice of Ocean Energy technologies
 
Module Learning Outcome
On successful completion of this module the learner will be able to:
# Module Learning Outcome Description
MLO1 Evaluate and apply basic and advanced OE technologies.
MLO2 Formulate theoretical understanding of water waves in general, both as regular and statistical processes, and apply and integrate this knowledge to the solution of ocean energy problems.
MLO3 Evaluate advanced theoretical knowledge of tidal streams and the tidal stream conversion process.
MLO4 Interpret advanced theoretical understanding of the estimation of wave forces on offshore structures and floating bodies using Morison's Equation and Froude-Krylov in the context of marine structures for ocean energy and the estimation of exciting forces on wave energy devices.techniques.
MLO5 Apply advanced theoretical hydrodynamics to model multiple body, multiple degree of freedom dynamic behaviour to estimate the dynamic behaviour of a single, and multiple, wave power devices.
MLO6 Assess and evaluate knowledge gained to several wave energy technologies for offshore and shore mounted operation, and estimate how an effective wave energy converter responds to waves.
MLO7 Design Narrow Wave tank experiments on selected devices and evaluate the results from such experiments.
Pre-requisite learning
Module Recommendations
This is prior learning (or a practical skill) that is strongly recommended before enrolment in this module. You may enrol in this module if you have not acquired the recommended learning but you will have considerable difficulty in passing (i.e. achieving the learning outcomes of) the module. While the prior learning is expressed as named DkIT module(s) it also allows for learning (in another module or modules) which is equivalent to the learning specified in the named module(s).
No recommendations listed
 
Module Indicative Content
Gravity Waves on Water.
Regular Waves Airy Wave Theory, irregular Waves Statistical description, Wave Spectra, Energy, Power
Interaction between Waves and Fixed and Floating Bodies.
6 degree of Freedom Model, Added mass matrix, added damping matrix, exciting force Vector, solving equation of motion frequency and time domain. Haskind relations, exciting force and added damping relation, Diffraction force on Fixed bodies including cylinder, sphere. Froude Krylov approximation for small bodies. Hydrodynamics and equations of Motion for Axisymmetric bodies. Equation of motion in the frequency and time domains for a single degree of freedom body
Wave power absorption in Regular and irregular waves.
Wave power absorption and optimisation in 1 degree of freedom, 2 degrees of freedom, and multiple degrees of freedom.
Power absorption and equations of motion for point absorbers
slender bodies articulated devices, oscillating water columns.
Introduction to Hydro elasticity and Offshore Structural Design principles.
n/a
Narrow wave tank- hydrodynamics of OWC and 2d floating structures, diffraction force estimation, power absorption.
n/a
Module Assessment
Assessment Breakdown%
Course Work30.00%
Final Examination70.00%
Module Special Regulation
 

Assessments

Full Time On Campus

Course Work
Assessment Type Written Report % of Total Mark 10
Marks Out Of 0 Pass Mark 0
Timing n/a Learning Outcome 4,6
Duration in minutes 0
Assessment Description
Laboratory Exercise 1.Typical content includes the numerical simulation of loads and moments on offshore structures using established techniques. Typical written report to include discussion of theories, applicability and limitations of theories, presentation of results in graphical format, and discussion of results.
Assessment Type Written Report % of Total Mark 10
Marks Out Of 0 Pass Mark 0
Timing n/a Learning Outcome 6,7
Duration in minutes 0
Assessment Description
Laboratory Exercise 2.Typical content to include numerical simulation work using BEM codes to model a single degree of freedom WEC in the frequency domain. Written report to typically present the theoretical basis of the modelling the WEC, describe the detailed process of modelling the WEC, discussing applications and limitations of the method, describe how the method may be used in conjunction with tank testing in the development process of a WEC and presenting results in graphical form.
Assessment Type Written Report % of Total Mark 10
Marks Out Of 0 Pass Mark 0
Timing n/a Learning Outcome 6,7
Duration in minutes 0
Assessment Description
Laboratory Exercise 3.This assessment typically follows on from Laboratory Exercise 2, and models a WEC in the time domain using a state-space modelling framework. Written report will typically describe the time domain modelling process, present time domain results for regular waves and discuss ways in which the simulations may be made computationally efficient. Results may be compared to the results obtained from narrow tank testing.
No Project
No Practical
Final Examination
Assessment Type Formal Exam % of Total Mark 70
Marks Out Of 0 Pass Mark 0
Timing End-of-Semester Learning Outcome 1,2,3,4,5,6
Duration in minutes 0
Assessment Description
End-of-Semester Final Examination
Reassessment Requirement
A repeat examination
Reassessment of this module will consist of a repeat examination. It is possible that there will also be a requirement to be reassessed in a coursework element.

DKIT reserves the right to alter the nature and timings of assessment

 

Module Workload

Workload: Full Time On Campus
Workload Type Contact Type Workload Description Frequency Average Weekly Learner Workload Hours
Lecture Contact No Description Every Week 2.00 2
Practical Contact No Description Every Week 2.00 2
Tutorial Contact No Description Every Week 1.00 1
Directed Reading Non Contact No Description Every Week 3.00 3
Independent Study Non Contact No Description Every Week 4.00 4
Total Weekly Learner Workload 12.00
Total Weekly Contact Hours 5.00
This module has no Part Time On Campus workload.
 
Module Resources
Recommended Book Resources
  • DCENR. (2014), Offshore Renewable Energy Development Plan, DCENR, Dublin.
  • DCENR. (2018), Offshore Renewable Energy Development Plan (OREDP) Interim Review.
  • Pecher, A. and Kofoed J. P.. (2017), Handbook of Ocean Wave Energy, Spring Open, [ISBN: 978-331939888].
  • Cruz, J.. (2010), Ocean Wave Energy, Illustrated Edition, Springer Berlin, [ISBN: 978-364209431].
  • Boyle, G. (2012), Renewable Energy:Power for a Sustainable Future, Oxford University Press, [ISBN: 0199681279].
  • Peter Bacon & Associates. Analysis of the Potential Economic Benefits of Developing OE in Ireland, ESBI.
  • Previsic ,Mirko. (2002), E2I EPRI ASSESSMENT Offshore Wave Energy Conversion devices, Report E2I EPRI WP-004-US JUNE 2004.
  • Chakbarti,K. (1994), Hydrodynamics of Offshore Structures offshore structures, CMP Boston.
  • Sarpkaya,T ,Isaacson ,M.. Mechanics of wave Forces on offshore structures, Van Nostrand Rheinhold.
  • Falnes Johanes, Ocean waves and Oscillating Systems ISBN 13-978-0-021-01749-7.
  • Department Of Agriculture and Marine. (2013), Harnessing Our Ocean Wealth, Dublin.
Supplementary Book Resources
  • Barbarit, A.. (2015), database of capture width ratio of wave energy converters.
  • Briggs Michael, McCormick Michael. (2004), Civil Engineering in the Oceans, ASCE.
This module does not have any article/paper resources
Other Resources