Course Name: Introduction to Marine Engineering

Degree:

Code

Year/Semester

Local Credits

ECTS Credits

Course Implementation, Hours/Week

Course

Tutorial

Laboratory

SMME 111

1

2

3

2

-

-

Department

Naval Architecture and Marine Engineering

Instructors

Tolunay KAYAARASI

Contact Information

  tkayaarasi@pirireis.edu.tr     

Office Hours

Web page

www.pirireis.edu.tr

Course Type

 Compulsory

Course Language

English

Course Prerequisites

  None

Course Category by Content, %

Basic Sciences

Engineering Science

Engineering Design

Humanities

10

90

-

-

Course Description

The ship and main systems; Engineering Operations; Engineering management

Course Objectives

1. To introduce ships and ships’ main systems to the students
2. To introduce engineering operations, to the Students,
3. To introduce engineering management, to the Students.

Course Learning Outcomes

Students who successfully pass the course will acquire knowledge and skills as listed below.

1. Ship and main systems: Ship types and ship structure; Main Propulsion Power; Auxiliary Machinery and Systems; Electrical System.
2. Engineering Operations:  Instrumentation System; Automation System; Fire Warning; Fire Alarm and Fighting System; Engineering Records and Reports; Engineering Analysis and Calculations; Workshop Facilities.
3. Engineering management: Engineering Authorizations; Engineering Responsibilities; Engineering Ethics; Watchkeeping and Equipment relevant.

Instructional Methods and Techniques

1. Theoretical lectures at classroom, presentations on board and projection on screen, hard print outs and soft e-learning material
2. Midterm and Final Exams
3. Introduction to Engine Room Simulator, two hours

Tutorial Place

-

Co-term Condition

-

Textbook

Introduction to Marine Engineering. By D.A. Taylor. (Available at Library)

Other References

BOLTON, W., B.H., Engineering Science, Newnes Co., 1990

WRIGHT, P.H., A. KOBLASZ, W.E. SAYLE II, Introduction to Engineering, John Willey and Sons Inc., NY, 1989

Craver, W.L.; Schroder, D.C.; Targuin, A.J.; Introduction to Engineering, Holt, Rinehart and Winston, NY, 1987

Eglinton, W.D.; Marine Rooms Blue Book, Cornell Maritime Press, Inc., 1993

Homework & Projects

Students will be required to provide various lists and sketches in homework handouts, relevant to ship machineries and operations, to aid their efforts to follow the development of the course content and to prepare for the examinations.

Laboratory Work

Duties, relations and operations of the machineries on board ships will be introduced to the students via Engine Room Simulatör.

Computer Use

-

Other Activities

-

 Assessment Criteria

Activities

Quantity

Effects on Grading, %

Attendance

-

-

Midterm

1

40

Quiz

-

-

Homework

1

If the Midterm grade is 35 and above, 10 points will be added to the Midterm grade.

Term Paper/Project

1

If the Final grade is 35 and above, 10 points will be added to the Final grade.

Laboratory Work

-

-

Practices

-

-

Tutorial

-

-

Seminar

-

-

Presentation

-

-

Field Study

-

-

Final Exam

1

60

TOTAL

100

Effects of Midterm on Grading, %

40

Effects of Final on Grading, %

60

TOTAL

100

ECTS/

WORKLOAD TABLE

Activities

Count

Hours

Total

Workload

Lecture

14

2

28

Midterm

 1

6

 5

Quiz

-

-

-

Homework

1

6

5

Term Paper/Project

1

6

5

Laboratory Work

-

-

-

Practices

-

-

-

Tutorial

 -

 -

 -

Seminar

-

-

-

Presentation

-

-

-

Field Study

-

-

-

Final Exam

1

7

7

Total Workload

50

Total Workload/25

2

Course ECTS Credits

3

Weeks

Topics

Course Outcomes

1

The shipyard, Ship design, Ship construction, The ship, Type of ships, Ships machinery

I-I

 Diesel engines, Boilers, Steam turbines, Gas turbines, Shafting, Propellers, Rudder and steering gear

I-II

2

Tanks, Pumps, Pipes, Valves, Pressurized air system, Air compressors, Turbo chargers, Refrigeration, Air-conditioning, Desalination plant, SCR, Incinators, Separators

I-III

3

Fuel oil system, Lub-oil system, Cooling system, Heat exchangers, Bilge water system, Ballast water system, Balancing system, Auxiliary boilers

I-III

4

Sea water system, Fresh water system, Deck machinery, Hull equipment, Disinfection system

I-III

5

Shore connection, Main diesel-generators, Emergency diesel-generators, Shaft generators, Turbo generators, Generator control boards

I-IV

6

Main switch board, High voltage gear, Low voltage gear, Distribution boards, Emergency distribution boards, Transformers, Batteries, Lighting, Emergency lighting, Grounding, Electric energy consumers

I-IV

7

Measurement, Calibration, Tuning

II-I

Main propulsion system, Auxiliary systems, Electrical plant, Bridge, Set values, Operating values; Engine Room Simulator.

II-II

Detection system, Alarm system, Fighting systems, Scavenging fires, Oil mist fires, Exhaust fires, Funnel fires, Engine room fires, Electrical fires, Bilge fires

II-III

8

Delivery of Home Work, Midterm Exam

-

9

Feed water, Fuel oil, Lub-oil, Fresh water

II-IV

10

Engineering records

II-V

Engineering reports

II-VI

Estimation of fuel consumption

II-VII

11

Work benches, Work wrenches, Lathe, Borer, Chain scale

II-VIII

12

Technical drawings, Installation manuals, Operation manuals, Maintenance manuals, Spare parts catalogs, Engineering regulations, Engineering orders

II-IX

12

Engineering terms and phrases

II-X

SI units

II-XI

Engineering tools

II-XII

13

Authorization and responsibilities, Goals, objectives and Tools; Engineering Library

III-I

14

Ethics of Ship Engineering, Watchkeeping and equipment operation

III-II

Delivery of Project

-

Marine Engineering Program Outcomes

Approach and Application

Level of Contribution

1

2

3

PO1: The ability to have knowledge of mathematics, science and engineering within the scope of Marine Engineering and to use this knowledge theoretically and practically.

Theoretical lecture, classroom practice, laboratory, independent learning, collaborative learning

X

PO2: The ability to define, formulate and solve complex engineering problems within the scope of Marine Engineering and the ability to choose and apply appropriate analysis and modeling methods for this purpose.

Theoretical lecture, classroom practice, industrial practice, laboratory, independent learning, collaborative learning

X

PO3: Ability to design complex Marine Engineering systems, processes, devices or products to meet specific requirements under realistic constraints and conditions, and the ability to select and apply modern design methods for this purpose

Theoretical course, classroom practice, industrial practice, laboratory, scientific research, computer-based applications and designs, independent learning, collaborative learning

X

PO4: The ability to select and use modern techniques and tools required for the analysis and solution of complex problems encountered in Marine Engineering applications, and the ability to use information technologies effectively

Theoretical lecture, classroom practice, industrial practice, case studies, independent learning, collaborative learning

X

PO5: Ability to design, conduct experiments, collect data, analyze and interpret results for the study of complex Marine Engineering problems or research topics

Theoretical course, classroom practice, laboratory, independent learning, cooperative learning, design, experiment and analysis applications

X

PO6: Ability to carry out interdisciplinary and multi-disciplinary teamwork and individual study skills

Theoretical course, design and project preparation studies

X

PO7: A competent knowledge of a foreign language with the ability to communicate effectively in oral and written; ability to write effective reports and understand written reports, to prepare design and production reports, to make effective presentations, to give and receive clear and understandable instructions; ability to communicate effectively orally and in writing in Maritime English

Theoretical lecture, classroom practice, industrial practice, case studies, independent learning, collaborative learning

X

PO8: Awareness of the necessity of lifelong learning; ability to access information, follow developments in science and technology, and constantly renew themselves

Theoretical lecture, classroom practice, independent collaborative learning

X

PO9: Knowledge of ethical principles, professional and ethical responsibility, and standards used in engineering practices

Theoretical lecture, classroom practice, independent collaborative learning

X

PO10: Knowledge of professional practice, such as project management, risk management and change management; awareness of entrepreneurship, innovation; To have knowledge, leadership and managerial skills about sustainable development

Theoretical lecture, classroom practice, independent collaborative learning

X

PO11: To have comprehensive knowledge, skills and awareness of the legal consequences of engineering solutions on the effects of Marine Engineering applications on marine safety and security, marine environment and health; To have knowledge about international and national maritime law and regulations

Theoretical lecture, classroom practice, independent collaborative learning

X

PO12: To have knowledge about quality management issues in the field of Marine Engineering

Theoretical lecture, classroom practice, independent collaborative learning

X

PO13: To have knowledge about maritime customs and traditions

Theoretical lecture, classroom practice, independent collaborative learning

X

Course

Outcomes

I

II

III

Programme Outcomes

1

X

2

X

3

X

4

X

5

X

6

X

7

X

8

X

9

X

10

X

11

X

12

X

13

X