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GIML7003 | Struc. Des. and Mat. of Small Boats | 3+0+0 | ECTS:7.5 | Year / Semester | Spring Semester | Level of Course | Third Cycle | Status | Elective | Department | DEPARTMENT of NAVAL ARCHITECTURE and MARINE ENGINEERING | Prerequisites and co-requisites | None | Mode of Delivery | | Contact Hours | 14 weeks - 3 hours of lectures per week | Lecturer | Prof. Dr. Ercan KÖSE | Co-Lecturer | | Language of instruction | | Professional practise ( internship ) | None | | The aim of the course: | Investigating the assumptions for design loads on ships
Strength analysis of local ship structures using matrix displacement method
Application of the finite element method to the ship structural problems
Understanding of the advanced strength issues such as plate buckling and bending
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Programme Outcomes | CTPO | TOA | Upon successful completion of the course, the students will be able to : | | | PO - 1 : | have knowledge about strength based solution methods, used in naval architecture | 1,2,11 | 1,3 | PO - 2 : | understand the solution of ship structure strength problems | 1,2,6,11 | 1,3 | PO - 3 : | understand the analysis of ship plane frame structures, continuous beams, etc. using matrix deplasman method | 1,2,11 | 1,3 | PO - 4 : | solve ship structure problems on their own | 1,2,10,11 | 1,3 | CTPO : Contribution to programme outcomes, TOA :Type of assessment (1: written exam, 2: Oral exam, 3: Homework assignment, 4: Laboratory exercise/exam, 5: Seminar / presentation, 6: Term paper), PO : Learning Outcome | |
Loads, response. Hull girder response analysis. Calculation of hull girder shear stress.Matrix methods: frames and grillages. Basic aspects of finite element method. Plate bending. Orthotropic plate bending. Buckling. Elastic buckling of stiffened panels. Plastic frame analysis. Linear-elastic and elastic-plastic fracture mechanics. Fatigue. Forced vibrations, modal analysis, the frequency-response method. |
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Course Syllabus | Week | Subject | Related Notes / Files | Week 1 | Introduction, loads, hull girder response analysis | | Week 2 | Hull girder response analysis , hull girder response analysis (shear force) | | Week 3 | Hull girder shear stress analysis (shear force) | | Week 4 | Hull girder shear stress analysis (torsion moment) | | Week 5 | Introduction to Matrix Displacement Method and comparison with the conventional methods. | | Week 6 | Line element types, and element stiffness matrices. | | Week 7 | Local and global coordinate system, code numbering method and system stiffness matrix. | | Week 8 | Sign convention, element and system load vector | | Week 9 | Mid Term Exam | | Week 10 | Orthotropic plate bending | | Week 11 | Buckling. Elastic buckling of stiffened panels | | Week 12 | Linear-elastic and elastic-plastic fracture mechanics. Fatigue | | Week 13 | Forced vibrations, modal analysis | | Week 14 | The frequency-response method | | Week 16 | Final Exam | | |
Method of Assessment | Type of assessment | Week No | Date | Duration (hours) | Weight (%) | Mid-term exam | 9 | | 2 | 50 | End-of-term exam | 15 | | 2 | 50 | |
Student Work Load and its Distribution | Type of work | Duration (hours pw) | No of weeks / Number of activity | Hours in total per term | Yüz yüze eğitim | 3 | 13 | 39 | Sınıf dışı çalışma | 2 | 10 | 20 | Arasınav için hazırlık | 4 | 2 | 8 | Arasınav | 2 | 1 | 2 | Dönem sonu sınavı için hazırlık | 5 | 3 | 15 | Dönem sonu sınavı | 2 | 1 | 2 | Total work load | | | 86 |
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