Back

Ship Geometry and Hydrostatics

 

 

PİRİ REİS UNIVERSITY

FACULTY OF ENGINEERING

Naval Architecture and Marine Engineering Programme

 

Ship Geometry and Hydrostatics

Degree:

 

Code

 

 

Year/Semester

 

Local Credits

 

ECTS Credits

 

Course Implementation, Hours/Week

Course

Tutorial

Laboratory

NAME211

Fall

3

4

2

2

 

Department

Naval Architecture and Marine Engineering

Instructors

 

Dr. Murat ÖZBULUT

Contact Information

 

mozbulut@pirireis.edu.tr

Office Hours

Tuesday 11.00-13.00

Web page

pruonline

Course Type

 Compulsory

Course Language

English

Course Prerequisites

  None

Course Category by Content, %

Basic Sciences

Engineering Science

Engineering Design

Humanities

10

30

60

 

Course Description

Introduction, terminology, ship types, principal dimensions, hull form coefficients, non-dimensional ratios, ship geometry, geometrical ship design, ship forms, lines plan, numerical integration, hydrostatic calculations

 

Course Objectives

 

Students learn the basics of ship form and ship geometry. They gain the ability of drawing the hull form plans, calculating the basic hydrostatic characteristics, determining the geometrical coefficients of a ship and lerning the basic terminology of ship geometry terms. 

 

Course Learning Outcomes

 

Students who successfully pass the course will;

  1.  Learn principal dimensions and ship geometry,

II .   Learn the different ship hull forms,

  1.  Draw the lines plan,
  2. Calculate hydrostatic values,  be aware of basic characteristics

 

 

Instructional Methods and Techniques

 

Tutorial Place

 

Co-term Condition

 

Textbook

Eric TUPPER,Introduction to Naval Architecture

Other References

RAWSON, K. J. (2001). Basic Ship Theory

 

Homework & Projects

3 projects will be assigned for each student.

Laboratory Work

 

Computer Use

Autocad will be used for drawings.

Other Activities

 
                   

 

 

 

 

Assessment Criteria

Activities

Quantity

Effects on Grading, %

Attendance

 

 

Midterm

1

25

Quiz

 

 

Homework

 

 

Term Paper/Project

3

40

Laboratory Work

 

 

Practices

 

 

Tutorial

 

 

Seminar

 

 

Presentation

 

 

Field Study

 

 

Final Exam

 1

35

TOTAL

 

%100

Effects of Midterm on Grading, %

 

%65

Effects of Final on Grading, %

 

%35

TOTAL

 

%100

 

ECTS/

WORKLOAD TABLE

Activities

Count

Hours

Total

Workload

Lecture

14

4

56

Midterm

1

3

3

Quiz

 

 

 

Homework

3

4

12

Term Paper/Project

 

 

 

Laboratory Work

 

 

 

Practices

 

 

 

Tutorial

 

 

 

Seminar

 

 

 

Presentation

 

 

 

Field Study

 

 

 

Final Exam

1

5

5

Total Workload

 

 

75

Total Workload/25

 

 

75/25=3.00

Course ECTS Credits

 

 

3

 

 

 

Week

 

Topics

Course Outcomes

1

Introduction / Ship types

I

2

Main dimensions,  form coefficients, non-dimensional ratios

I-II

3

Ship geometry, hull form plans, hull form drawing essentials

I-II

4

Basic properties of Series 60 forms, preparing offset table,  Drawing net lines,

I-III

5

Cross sections, water lines and profiles

II-III

6

Drawing the control curves (buttocks, diagonals), Drawing ship lines by using Autocad

II-III

7

Hydrostatic characteristics ,Numerical integration tech.

II-III

8

Calculation area and volume by using numerical integration, Sectional area curve and calculating displacement

II-III

9

Midterm

 

10

Calculating center of area and volume (LCF, LCB, KB)

IV

11

Moment of inertia  (IT, IL) Inital Stability- Metacenter, BMT BML

I-IV

12

Hydrostatic calculations  of a given ship

IV

13

Hydrostatic curves

IV

14

Hydrostatic curves

IV

 

 

 

 

 

 

 

 

 

Relationship between the Course and the Naval Architecture and Marine Engineering Curriculum

 

 

Program Outcomes

Level of Contribution

1

2

3

a

An ability to apply knowledge of mathematics, science, and engineering

 

 

 

b

An  ability to design and conduct experiments, as well as to analyze and interpret data

X

 

 

c

An ability to design a system, component or process to meet desired needs

X

 

 

d

Ability to function on multi-disciplinary teams

 

 

 

e

An ability to identify, formulate, and solve engineering problems

X

 

 

f

An understanding of professional and ethical responsibility

 

 

 

g

An ability to communicate effectively

 

 

 

h

The broad education necessary to understand the impact of engineering solutions in a global and societal context

 

 

 

i

A recognition of the need for, and an ability to engage in life-long learning

 

 

 

j

A knowledge of contemporary issues

 

 

 

k

An ability to use the techniques, skills and modern engineering tools necessary for engineering practice

 

X

 

l

an ability to apply basic knowledge in fluid mechanics, structural mechanics, material properties, and energy/propulsion systems in the context of marine vehicles

 

X

 

 

         1: Small, 2: Partial, 3: Full

 

Programme Outcomes & Course Outcomes Connectivity Matrix

 

Course

Outcomes

I

II

III

 

 

IV

Programme Outcomes

a

      

X

b

    

X

 

c

  

X

  

X

d

      

 

e

X

    

 

f

      

 

g

      

 

h

      

 

i

      

 

j

      

 

k

X

  

X

X

l

  

X

  

 

 

 

 

Prepared by

         Dr. Murat ÖZBULUT

Date

17.09.2018

Signature