Semester 1

^st

Semester

Person responsible Prof. Ir. Mukhtasor, M.Eng., Ph.D.

for the module

Lecturer Prof. Ir. Mukhtasor, M.Eng., Ph.D.

Dr. Eng. Shade Rahmawati S.T., M.T.

Dr. Dendy Satrio, S.ST.

Language Indonesian

Relation to curriculum Mandatory course for master degree program in Ocean Engineering, 1

^st

semester.

Type of teaching,

contact hours Lecture, <50 students

150 minutes x 16 weeks per semester Workload 4. Class, 3 × 50’ = 150 minutes per week

5. Independent Study, 3 × 60’ = 180 minutes per week 6. Structured Activities, 3 × 60’ = 180 minutes per week Credit points 3 CREDITS ~ 4.8 ECTS

CREDITS × 1.6 ECTS Requirements according

to the examination regulations

A student must have attended at least 80% of the lectures to sit in the exams.

Recommended

prerequisites -

Learning outcomes and their corresponding PLOs

CLO.1. Able to understand the principal parameter measurement (bathymetry, tide, current, wave and ocean thermal) and calculate marine energi potential by considering the previous parameters

CLO.2. Able to understand and estimate the theoretical, practical,

accessible, and viable potential of each marine energi source.

CLO.3. Able to understand the marine energi conversion technology on different energi source such as tide, current, wave, wind and ocean thermal.

CLO.4. Able to understand offshore structure to support ocean energy conversion systems.

CLO.5. Able to understand the analysis method of offshore structure to support ocean energy conversion systems.

CLO.6. Able to analyse the offshore structure to support ocean energy conversion systems.

CLO.7. Able to understand the economic and environment impact of ocean energy conversion systems CLO.8.

LO.6. Able to formulate new research questions to accomodate

multidisciplinary

knowledge for technology development in the field of design and construction of marine structures

CLO.4. Able to understand offshore structure to support ocean energy conversion systems.

CLO.5. Able to understand the analysis method of offshore structure to support ocean energy conversion systems.

CLO.6. Able to analyse the offshore structure to support ocean energy conversion systems.

CLO.7. Able to understand the economic and environment impact of

ocean energy conversion systems

Study and examination requirements and forms of examination

 In-class exercise

 Assignment

 Mid-term exam

 Final exam

Media employed Offline: LCD, whiteboard, PowerPoint presentation

Online: websites (myITS Classroom), Zoom, Microsoft Teams,

PowerPoint presentation, FAST.

Reading list Main:

1. Mukhtasor (2015), Mengenal Energi Laut, ICEES (Indonesian Counterpart for Energy and Environmental Solutions)

2. Lynn, Paul A (2014), Electricity from Wave and Tide: An Introduction to Ocean energy, John Wiley & Sons Ltd, Chennai India

3. Constans, J., (1979), Marine Sources of Energy, Pergamon Press, New York

4. McCormick, M.E., (1980), Ocean Wave Energy Conversion System. John Wiley Son, Inc, New York

5. Vega, Luis A (2012), Ocean Thermal Energy Conversion in Encyclopedia of Sustainability Science and Technology, Springer

6. Avery, William H, and W, Chih (1994), Renewable Energy from the Ocean: A Guide to OTEC. New York, Oxford University Press Optional: Inc.

1. Nihous, G.C (2007), A Preliminary Assessment Of Ocean Thermal Energy Conversion Resources, Journal of Energy Resources Technology

2. Emily Rudkin (2001), Survey of Energy Resources Marine Current Energy, World Energy Council, London UK

3. Maitre, et al. (2005). Marine Turbine Development :Numerical and Experimental Inevestigation

4. Graff, W.J.(1981), Introduction to Offshore Structures, Gulf Publisher, London

5. McClelland, B. and Reifel, M.D. (1986), Planning and Design of Fixed Offshore Platforms, Van Nostrand Reinhold Co., New 6. Hsu, T. H.(1984), Applied Offshore Structural Engineering, Gulf York

Publishing Co.,

7. Dawson, T.H. (1983.), Offshore Structural Engineering, Prentice-Hall, Inc., New Jersey

8. Baltrop, N.D.P, et all (1991), Dynamics of Fixed Marine Structures, 3th edition, Butterworth-Heinemann Ltd.

9. Subrata K. Chakrabarti (2005), Handbook of Ocean Engineering, Elsevier, London

10. El-Reedy, Muhammed A. (2012), Offshore Structures: Design,

Construction and Maintenance, Elsevier, Amsterdam

Bahan Kajian Dalam mata kuliah ini mahasiswa akan mempelajari pokok-pokok bahasan sebagai berikut:

1. Konteks dan sejarah perkembangan energi laut di dunia dan Indonesia

2. Pengukuran data oseanografi untuk keperluan sistem konversi energi laut (bathymetry, pasang surut, arus, gelombang dan panas laut) 3. Prinsip dan perhitungan potensi energi laut

4. Klasifikasi potensi energi laut (teoritis, teknis, praktis, accessible dan viable) dan potensi energi laut Indonesia

5. Prinsip, teknologi dan teknis konversi energi laut (pembangkit listrik tenaga pasang surut, pembangkit listrik tenaga arus laut, pembangkit listrik tenaga gelombang laut, pembangkit listrik tenaga panas laut (OTEC), pembangkit listrik tenaga angin laut.

6. Prinsip dan jenis struktur bangunan lepas pantai penopang sistem konversi energi laut (jenis terpancang, compliant dan terapung).

7. Metodologi analisis struktur bangunan lepas pantai penopang sistem konversi energy laut 8. Analisis dampak ekonomi dan lingkungan sistem konversi energi laut

9. Analisis atau pemodelan berbasis komputer struktur bangunan lepas pantai penopang sistem konversi energi laut.

10. Studi kasus

Program StudiStudy Program S2 Teknik KelautanMaster of Ocean Engineering

Mata KuliahCourse Sistem Konversi Energi LautOcean Energy Conversion System Kode Mata KuliahCourse Code MO185104MO1851024

SemesterSemester 1^st

SKSCredit 3

RP-S2 Dosen PengampuLecturer Prof. Ir. Mukhtasor, M.Eng., Ph.D.; Dr. Eng. Shade Rahmawati S.T., M.T.; Dr. Dendy Satrio, S.ST.

Study Materials The students will get the following materials:

1. Historic development of ocean energy technology in Indonesia and worldwide

2. Oceanography data measurement for ocean energy conversion system, including bathymetry, tide, current, wave, and ocean thermal 3. Principal calculation method of ocean energy potential

4. Ocean energy potential classification including theoretical, practical, accessible and viable, in Indonesia and worldwide

5. Existing ocean energy conversion technology in the world (tide, current, wave, ocean thermal and wind based power plant) and its principal working method

6. Offshore structure types to support ocean energy conversion systems, including fixed, compliant and floating type 7. Structural analysis method of the offshore structure to support ocean energy conversion systems

8. The economic and environment impact of ocean energy conversion systems

9. Numerical-based modeling and investigation of the offshore structure to support ocean energy conversion systems 10. Case study

CPL yang dibebankan MK Mampu merumuskan pertanyaan penelitian baru untuk mengakomodasi pengetahuan multidisiplin untuk pengembangan teknologi di bidang desain dan konstruksi struktur laut

PLO Able to formulate new research questions to accomodate multidisciplinary knowledge for technology development in the field of design and construction of marine structures

CP-MK 1. Mahasiswa memahami prinsip pengukuran parameter (bathymetry, pasang-surut, arus, gelombang dan panas laut) dan mampu menghitung potensi energi laut dengan mempertimbangan parameter-parameter tersebut

2. Mahasiswa memahami prinsip dan mampu menerapkan konsideran yang tepat dalam perhitungan jenis-jenis potensi energi laut (potensi teoritis, potensi teknis, potensi praktis, potensi accessible dan potensi viable)

3. Mahasiswa memahami prinsip, teknologi dan teknik konversi energi laut menjadi listrik dari jenis energi pasang surut, arus laut, gelombang dan panas laut

4. Mahasiswa memahami prinsip dan jenis struktur bangunan lepas pantai penopang sistem konversi energi laut 5. Mahasiswa memahami metodologi analisis struktur bangunan lepas pantai penopang sistem konversi energy laut 6. Mahasiswa mampu melakukan analisis struktur bangunan lepas pantai penopang sistem konversi energy laut 7. Mahasiswa memahami dampak ekonomi dan lingkungan sistem konversi energi laut

CLO 1. Able to understand the principal parameter measurement (bathymetry, tide, current, wave and ocean thermal) and calculate ocean energy potential by considering the previous parameters

2. Able to understand and estimate the theoretical, practical, accessible, and viable potential of each ocean energy source.

3. Able to understand the ocean energy conversion technology on different energy source such as tide, current, wave, wind, and ocean thermal.

4. Able to understand offshore structure to support ocean energy conversion systems.

5. Able to understand the analysis method of offshore structure to support ocean energy conversion systems.

6. Able to analyses the offshore structure to support ocean energy conversion systems.

7. Able to understand the economic and environment impact of ocean energy conversion systems

Program StudiStudy Program S2 Teknik KelautanMaster of Ocean Engineering

Mata KuliahCourse Sistem Konversi Energi LautOcean Energy Conversion System Kode Mata KuliahCourse Code MO185104MO1851024

SemesterSemester 1^st

SKSCredit 3

RP-S2 Dosen PengampuLecturer Prof. Ir. Mukhtasor, M.Eng., Ph.D.; Dr. Eng. Shade Rahmawati S.T., M.T.; Dr. Dendy Satrio, S.ST.

Perte- Meetingmuan

Kemampuan Akhir Sub CP-MK Final Ability

Keluasan (materi pembelajaran)Extent

(learning material)

Metode Pembelajaran

Learning methods

Estimasi Waktu Duration

Bentuk Evaluasi

Evaluation Type Kriteria dan Indikator Penilaian

Assessment Criteria and Indicators Bobot Penilaian

Scoring 1 Memahami dan mampu menjelaskan

konteks dan sejarah perkembangan energi laut di dunia dan Indonesia

Konteks dan sejarah perkembangan energi laut di dunia dan Indonesia

 Papara

n teori

 Handou

t Diskusi

3 × 50’  Pertanyaa

n-pertanyaan langsung di kelas

 Tugas:

studi literatur

Ketepatan dalam menjelaskan konteks dan sejarah perkembangan energi laut di dunia dan Indonesia

5%

Able to understand and explain the context and history of the development of ocean energy in the world and Indonesia

Context and history of ocean energy development in the world and Indonesia

 Theor

etical presentation

 Hando

ut Discus sion

 Question

s in class

 Assignm

ent: literature study

Accuracy in explaining the context and history of ocean energy development in the world and Indonesia

2-3 1. Memahami dan mampu menjelaskan konsep pengukuran data oseanografi untuk keperluan sistem konversi energi.

2. Memahami dan mampu menjelaskan jenis-jenis data oseanografi: batimetri, pasang surut, arus, gelombang, dan panas laut.

Pengukuran data oseanografi untuk keperluan sistem konversi energi laut (bathymetry, pasang surut, arus, gelombang dan panas laut)

 Papara

n teori

 Handou

t Diskusi

3 × 50’  Pertanyaa

n-pertanyaan langsung di kelas

 Tugas:

studi literatur

1. Ketepatan dalam menjelaskan konsep pengukuran data

oseanografi untuk keperluan sistem konversi energi

2. Ketepatan dalam menjelaskan jenis- jenis data oseanografi: batimetri, pasang surut, arus, gelombang, dan panas laut.

10%

1. Able to understand and be able to explain the concept of measuring oceanographic data for the purposes of energy conversion systems.

2. Able to understand and be able to explain types of oceanographic data:

bathymetry, tides, currents, waves, and ocean heat.

Measurement of oceanographic data for the purposes of ocean energy conversion systems (bathymetry, tides, currents, waves, and ocean thermal)

 Theor

etical presentation

 Hando

ut Discus sion

 Question

s in class

 Assignm

ent: literature study

1. Accuracy in explaining the concept of measuring oceanographic data for the purposes of energy conversion systems

2. Accuracy in explaining types of oceanographic data: bathymetry, tides, currents, waves, and ocean heat

Perte- Meetingmuan

Kemampuan Akhir Sub CP-MK Final Ability

Keluasan (materi pembelajaran) Extent (learning material)

Metode Pembelajaran

Learning methods

Estimasi Waktu Duration

Bentuk Evaluasi

Evaluation Type Kriteria dan Indikator Penilaian

Assessment Criteria and Indicators Bobot Penilaian

Scoring 4 Memahami dan mampu menjelaskan

prinsip dan perhitungan potensi energi laut

Prinsip dan perhitungan

potensi energi laut  Papara n teori

 Handou

t Contoh

 Diskus

i

3 × 50’  Pertanyaa

n-pertanyaan langsung di kelas

 Tugas:

studi literatur

Ketepatan dalam menjelaskan prinsip

dan perhitungan potensi energi laut 5%

Able to understand and be able to explain the principles and calculations of ocean energy potential

Principles and calculations of ocean energy potential

 Theor

etical presentation

 Hando

ut Examp

le Discus sion

 Question

s in class

 Assignm

ent: literature study

Accuracy in explaining the principle and calculation of ocean energy potential

Program StudiStudy Program S2 Teknik KelautanMaster of Ocean Engineering

Mata KuliahCourse Sistem Konversi Energi LautOcean Energy Conversion System Kode Mata KuliahCourse Code MO185104MO1851024

SemesterSemester 1^st

SKSCredit 3

RP-S2 Dosen PengampuLecturer Prof. Ir. Mukhtasor, M.Eng., Ph.D.; Dr. Eng. Shade Rahmawati S.T., M.T.; Dr. Dendy Satrio, S.ST.

5 1. Memahami dan mampu menjelaskan klasifikasi potensi energi laut baik secara teoritis, teknis, praktis, accessible dan viable)

2. Memahami dan menjelaskan potensi energi laut Indonesia

Klasifikasi potensi energi laut (teoritis, teknis, praktis, accessible dan viable) dan potensi energi laut Indonesia

 Papara

n teori

 Handou

t Diskusi

3 × 50’  Pertanyaa

n-pertanyaan langsung di kelas

 Tugas:

studi literatur

1. Ketepatan dalam menjelaskan klasifikasi potensi energi laut baik secara teoritis, teknis, praktis, accessible dan viable) 2. Ketepatan dalam menjelaskan

potensi energi laut Indonesia

5%

1. Able to understand and be able to explain the classification of marine energy potential both theoretically, technically, practically, accessible, and viable)

2. Able to understand and explain Indonesia's marine energy potential

Classification of marine energy potential (theoretical, technical, practical, accessible and viable) and Indonesia's marine energy potential

 Theor

etical presentation

 Hando

ut Discus sion

 Question

s in class

 Assignm

ent: literature study

1. Accuracy in explaining the classification of marine energy potential both theoretically, technically, practically, accessible, and viable)

2. Accuracy in explaining Indonesia's marine energy potential

Perte- Meetingmuan

Kemampuan Akhir Sub CP-MK Final Ability

Keluasan (materi pembelajaran)Extent

(learning material)

Metode Pembelajaran

Learning methods

Estimasi Waktu Duration

Bentuk Evaluasi

Evaluation Type Kriteria dan Indikator Penilaian

Assessment Criteria and Indicators Bobot Penilaian

Scoring

6-7 1.Memahami dan menjelaskan prinsip, teknologi dan teknis konversi energi laut

2.Memahami dan menjelaskan definisi dan cara kerja pembangkit listrik tenaga pasang surut, pembangkit listrik tenaga arus laut, pembangkit listrik tenaga gelombang laut, pembangkit listrik tenaga panas laut (OTEC), pembangkit listrik tenaga angin laut

Prinsip, teknologi dan teknis konversi energi laut (pembangkit listrik tenaga pasang surut, pembangkit listrik tenaga arus laut, pembangkit listrik tenaga gelombang laut, pembangkit listrik tenaga panas laut (OTEC), pembangkit listrik tenaga angin laut.

 Papara

n teori

 Handou

t Diskusi

3 × 50’  Pertanyaa

n-pertanyaan langsung di kelas

 Tugas:

studi literatur

1.Ketepatan dalam menjelaskan prinsip, teknologi dan teknis konversi energi laut

2.Ketepatan dalam menjelaskan definisi dan cara kerja pembangkit listrik tenaga pasang surut, pembangkit listrik tenaga arus laut, pembangkit listrik tenaga

gelombang laut, pembangkit listrik tenaga panas laut (OTEC),

pembangkit listrik tenaga angin laut

15%

1.Able to understand and explain the principles, technologies and techniques of marine energy conversion

2.Able to understand and explain the definition and workings of tidal power plants, ocean current power plants, ocean wave power plants, ocean thermal power plants (OTEC), ocean wind power plants

Principles, technology and techniques of marine energy conversion (tidal power plants, ocean current power plants, ocean wave power plants, ocean thermal energy conversion (OTEC), ocean wind power plants.

 Theor

etical presentation

 Hando

ut Discus sion

 Question

s in class

 Assignm

ent: literature study

1.Accuracy in explaining the principles, technology, and techniques of marine energy conversion

2.Accuracy in explaining the definition and workings of tidal power plants, ocean current power plants, ocean wave power plants, ocean thermal power

8 Evaluasi Tengah Semester

Mid Semester Evaluation 10%

Program StudiStudy Program S2 Teknik KelautanMaster of Ocean Engineering

Mata KuliahCourse Sistem Konversi Energi LautOcean Energy Conversion System Kode Mata KuliahCourse Code MO185104MO1851024

SemesterSemester 1^st

SKSCredit 3

RP-S2 Dosen PengampuLecturer Prof. Ir. Mukhtasor, M.Eng., Ph.D.; Dr. Eng. Shade Rahmawati S.T., M.T.; Dr. Dendy Satrio, S.ST.

9-10 1. Memahami dan mampu menjelaskan definisi dan fungsi serta subbagian dari struktur penopang turbin energy laut 2. Memahami dan mampu menjelaskan

karakteristik berbagai konsep struktur penopang turbin energy laut yang ada saat ini;

3.Memahami dan mampu menjelaskan karakteristik berbagai konsep struktur penopang turbin energy laut alternative sbg pengembangan yang ada.

Prinsip dan jenis struktur bangunan lepas pantai penopang sistem turbin listrik energi laut (jenis terpancang, compliant dan terapung, dll.).

 Papara

n teori

 Handou

t Diskusi

3 × 50’  Pertanyaa

n-pertanyaan langsung di kelas

 Tugas:

studi literatur

1. Ketepatan dalam menjelaskan definisi dan fungsi serta subbagian dari struktur penopang turbin energy laut;

2. Ketepatan dalam menjelaskan karakteristik berbagai konsep struktur penopang turbin energy laut yang ada saat ini;

3. Ketepatan dalam menjelaskan karakteristik berbagai konsep struktur penopang turbin energy laut alternative sebagai

pengembangan yang ada saat ini.

5%

3.Able to understand and be able to explain the definitions and functions and subsections of the marine energy turbine support structure;

4.Able to understand and be able to explain the characteristics of various concepts of marine energy turbine support structures that exist today;

5.Able to understand and be able to explain the characteristics of various concepts of alternative marine energy turbine support structures for existing developments.

Principles and types of offshore structures supporting marine energy power turbine systems (fixed, compliant and floating types, etc.).

 Theor

etical presentation

 Hando

ut Discus sion

 Question

s in class

 Assignm

ent: literature study

2. Accuracy in explaining the definition and function as well as subsections of the marine energy turbine support structure;

3. Accuracy in explaining the characteristics of various concepts of marine energy turbine support structures that exist today;

4. Accuracy in explaining the characteristics of various concepts of alternative marine energy turbine support structures as current developments.

Perte- Meetingmuan

Kemampuan Akhir Sub CP-MK Final Ability

Keluasan (materi pembelajaran) Extent (learning material)

Metode Pembelajaran

Learning methods

Estimasi Waktu Duration

Bentuk Evaluasi

Evaluation Type Kriteria dan Indikator Penilaian

Assessment Criteria and Indicators Bobot Penilaian

Scoring 11 1. Memahami dan mampu menjelaskan

karakteristik tiap jenis konsep turbin angin lepas pantai terapung jenis Barge, Spar dan TLP;

2. Memahami dan mampu menjelaskan perbandingan jenis konsep turbin angin lepas pantai terapung jenis Barge, Spar dan TLP.

Jenis & perbandingan konsep turbin jenis terapung (kasus: turbin angin lepas pantai terapung jenis Barge, Spar dan TLP)

 Papara

n teori

 Handou

t Diskusi

3 × 50’  Pertanyaa

n-pertanyaan langsung di kelas

 Tugas:

studi literatur

1. Ketepatan dalam menjelaskan karakteristik tiap jenis konsep turbin angin lepas pantai terapung jenis Barge, Spar dan TLP;

2. Ketepatan dalam menjelaskan perbandingan ketiga jenis konsep turbin angin lepas pantai terapung Barge, Spar dan TLP.

5%

Program StudiStudy Program S2 Teknik KelautanMaster of Ocean Engineering

Mata KuliahCourse Sistem Konversi Energi LautOcean Energy Conversion System Kode Mata KuliahCourse Code MO185104MO1851024

SemesterSemester 1^st

SKSCredit 3

RP-S2 Dosen PengampuLecturer Prof. Ir. Mukhtasor, M.Eng., Ph.D.; Dr. Eng. Shade Rahmawati S.T., M.T.; Dr. Dendy Satrio, S.ST.

1.Able to understand and be able to explain the characteristics of each type of floating offshore wind turbine concept of Barge, Spar and TLP types;

2.Able to understand and be able to explain the comparison of types of floating offshore wind turbine concepts of Barge, Spar and TLP types.

Types & comparison of floating turbine types (case: Barge, Spar and TLP floating offshore wind turbines)

 Theor

etical presentation

 Hando

ut Discus sion

 Question

s in class

 Assignm

ent: literature study

1. Accuracy in explaining the characteristics of each type of floating offshore wind turbine concept type Barge, Spar and TLP;

2. Accuracy in explaining the comparison of the three types of floating offshore wind turbine concepts Barge, Spar and TLP.

12-13 1. Mahasiswa dapat me­ma­hami dan mampu menjelaskan kondisi lingkungan & kondisi turbinnya;

2. Mahasiswa dapat me­ma­hami dan mampu menjelaskan proses fabrikasi dan instalasi turbin angin lepas pantai

Design Conditions turbin energy laut. Fabrikasi dan Instalasi turbin energy laut (kasus: turbin angin lepas pantai).

 Papara

n teori

 Handou

t Diskusi

3 × 50’  Pertanyaa

n-pertanyaan langsung di kelas

 Tugas:

studi literatur

1. Ketepatan dalam menjelas­kan kondisi lingkungan & kondisi turbinnya;

2. Ketepatan dalam menjelaskan proses fabrikasi dan instalasi turbin angin lepas pantai

10%

1.Able to understand and be able to explain environmental conditions &

turbine conditions

2.Able to understand and be able to explain the fabrication and installation process of offshore wind turbines.

Design Conditions for ocean energy turbines.

Fabrication and installation of ocean energy turbines (case:

offshore wind turbines).

 Theor

etical presentation

 Hando

ut Discus sion

 Question

s in class

 Assignm

ent: literature study

1. Accuracy in explaining

environmental conditions & turbine conditions.

2. Accuracy in explaining the fabrication and installation process of offshore wind turbines.

Perte- Meetingmuan

Kemampuan Akhir Sub CP-MK Final Ability

Keluasan (materi pembelajaran) Extent (learning material)

Metode Pembelajaran

Learning

Estimasi Waktu Duration

Bentuk Evaluasi

Evaluation Type Kriteria dan Indikator Penilaian

Assessment Criteria and Indicators Bobot Penilaian

Scoring

14 1. Memahami dan mampu menjelaskan tujuan dan tahapan proses desain struktur turbin angin lepas pantai ; 2. Memahami dan menjelaskan kriteria

desain turbin angin lepas pantai terpancang (kriteria operasional, kriteria konstruksi, kriteria lingkungan dan kriteria pembangunan dan instalasi)

Design Methodology (tujuan desain, proses desain & criteria desain) turbin energy laut (kasus: turbin angin lepas pantai)

 Papara

n teori

 Handou

t Diskusi

3 × 50’  Pertanyaa

n-pertanyaan langsung di kelas

 Tugas:

studi literatur

1. Ketepatan dalam menjelaskan tujuan dan tahapan proses desain struktur turbin angin lepas pantai.

2. Ketepatan dalam menjelaskan kriteria desain turbin angin lepas pantai terpancang (kriteria operasional, kriteria konstruksi, kriteria lingkungan dan kriteria pembangunan dan instalasi).

5%

1.Able to understand and explain the objectives and stages of the offshore wind turbine structure design process.

2.Able to understand and explain the design criteria of a fixed offshore wind turbine (operational criteria,

construction criteria, environmental criteria and construction and installation criteria)

Design Methodology (design objectives, design process & design criteria) marine energy turbines (case: offshore wind turbines)

 Theor

etical presentation

 Hando

ut Discus sion

 Question

s in class

 Assignm

ent: literature study

1. Accuracy in explaining the objectives and stages of the offshore wind turbine structural design process.

2. Accuracy in explaining the design criteria of a fixed offshore wind turbine (operational criteria, construction criteria, environmental criteria, and construction and

Perte- Meetingmuan

Kemampuan Akhir Sub CP-MK Final Ability

Keluasan (materi pembelajaran) Extent (learning material)

Metode Pembelajaran

Learning methods

Estimasi Waktu Duration

Bentuk Evaluasi

Evaluation Type Kriteria dan Indikator Penilaian

Assessment Criteria and Indicators Bobot Penilaian

Scoring

Program StudiStudy Program S2 Teknik KelautanMaster of Ocean Engineering

Mata KuliahCourse Sistem Konversi Energi LautOcean Energy Conversion System Kode Mata KuliahCourse Code MO185104MO1851024

SemesterSemester 1^st

SKSCredit 3

RP-S2 Dosen PengampuLecturer Prof. Ir. Mukhtasor, M.Eng., Ph.D.; Dr. Eng. Shade Rahmawati S.T., M.T.; Dr. Dendy Satrio, S.ST.

15 1. Mahasiswa dapat memahami dan mampu menjelaskan proses simulasi komputer dalam desain (input, desain awal & desain akhir);

2. Mahasiswa mampu melakukan pemodelan berbasis komputer untuk analisis suatu struktur sederhana berupa bangunan lepas pantai penopang sistem turbin listrik energi laut jenis monopile.

Pemodelan berbasis komputer struktur bangunan lepas pantai penopang sistem turbin listrik energy laut jenis monopile

 Papara

n teori

 Handou

t Contoh pemodelan

 Diskusi

3 × 50’  Pertanyaa

n-pertanyaan langsung di kelas

 Tugas:

studi literatur

1. Ketepatan dalam menjelaskan proses simulasi komputer dalam desain (input, desain awal & desain akhir);

2. Ketepatan dalam melakukan pemodelan berbasis komputer untuk analisis suatu struktur sederhana berupa bangunan lepas pantai penopang sistem turbin listrik energi laut jenis monopile.

15%

1.Students can understand and be able to explain the process of computer simulation in design (input, initial design

& final design);

2.Students are able to perform computer- based modeling for the analysis of a simple structure in the form of an offshore building supporting a monopile type marine energy power turbine system.

Computer-based modeling of offshore structures supporting monopile marine energy power turbine systems.

 Theor

etical presentation

 Hando

ut Model ling example

 Discus

sion

 Question

s in class

 Assignm

ent: literature study

1. Accuracy in explaining the process of computer simulation in the design (input, initial design & final design);

2. Accuracy in conducting computer- based modeling for the analysis of a simple structure in the form of an offshore building supporting a monopile type marine energy

16 Evaluasi Akhir Semester

Final Semester Evaluation 10%

PUSTAKA/REFERENCES:

Main:

1. Mukhtasor (2015), Mengenal Energi Laut, ICEES (Indonesian Counterpart for Energy and Environmental Solutions)

2. Lynn, Paul A (2014), Electricity from Wave and Tide: An Introduction to Ocean energy, John Wiley & Sons Ltd, Chennai India 3. Constans, J., (1979), Marine Sources of Energy, Pergamon Press, New York

4. McCormick, M.E., (1980), Ocean Wave Energy Conversion System. John Wiley Son, Inc, New York

5. Vega, Luis A (2012), Ocean Thermal Energy Conversion in Encyclopedia of Sustainability Science and Technology, Springer 6. Avery, William H, and W, Chih (1994), Renewable Energy from the Ocean: A Guide to OTEC. New York, Oxford University Press Inc.

Optional:

1. Nihous, G.C (2007), A Preliminary Assessment Of Ocean Thermal Energy Conversion Resources, Journal of Energy Resources Technology 2. Emily Rudkin (2001), Survey of Energy Resources Marine Current Energy, World Energy Council, London UK

3. Maitre, et al. (2005). Marine Turbine Development :Numerical and Experimental Inevestigation 4. Graff, W.J.(1981), Introduction to Offshore Structures, Gulf Publisher, London

5. McClelland, B. and Reifel, M.D. (1986), Planning and Design of Fixed Offshore Platforms, Van Nostrand Reinhold Co., New York 6. Hsu, T. H.(1984), Applied Offshore Structural Engineering, Gulf Publishing Co.,

7. Dawson, T.H. (1983.), Offshore Structural Engineering, Prentice-Hall, Inc., New Jersey

8. Baltrop, N.D.P, et all (1991), Dynamics of Fixed Marine Structures, 3th edition, Butterworth-Heinemann Ltd.

9. Subrata K. Chakrabarti (2005), Handbook of Ocean Engineering, Elsevier, London

10. El-Reedy, Muhammed A. (2012), Offshore Structures: Design, Construction and Maintenance, Elsevier, Amsterdam