欧洲知名院校海洋工程类专业介绍

1、ContentUniversity of Strathclyde4BEng Hons Naval Architecture with Ocean Engineering4Overview4Course Structure4Learning&teaching5Assessment6MEng Naval Architecture and Marine Engineering6Overview6Course Structure7Learning&teaching7Assessment8University of Southampton9MEng Ship Science /

2、 Naval Architecture9Overview9Programme structure9Typical course content10Special Requirements - All Courses10Modulus10MATH105410Mathematics for Engineering and the Environment10FEEG100411Electrical and Electronic Systems11FEEG100311Thermofluids11FEEG100212Mechanics, Structures and Materials12FEEG100

3、113Design and Computing13SESS101513Basic Naval Architecture13FEEG200115Systems Design and Computing15FEEG200515Materials and Structures15FEEG200616Engineering Management and Law16SESS201516Hydrodynamics and Seakeeping16SESS201617Ship Structural Design and Production17SESS201818Ship Powering and Cont

4、rol Surfaces18MATH204819Mathematics for Engineering and the Environment Part II19SESG300119Manufacturing with Metals19SESS300120Marine Hydrodynamics20SESS300321Advanced Naval Architecture21SESS300722Theory of Plate Structures22SESS301522Individual project (Ship)22SESS302023Marine Craft Concept Desig

5、n23SESS300624Marine Propulsion Engineering24SESS301924Ship Control Systems24SESG601125Group Design Project (GDP)25SESS600626Advances in Resistance and Propulsion26SESS600227Marine Safety & Environmental Engineering27SESS600327Maritime Fluid Structure Interaction27SESS600428Structural Integrity28

6、SESA603029Flow Control29SESG600730Materials in Transport30SESG601831Design Search & Optimisation 1: Principles, methods and parameterizations31SESS602131Applications of CFD31SESS605832Renewable Energy from the Environment32SESG301732Teaching and Communication and the Undergraduate Ambassador Sch

7、eme32SESS300933Finite Element Analysis33Delft University of Technology34BSc Marine Technology34At the top34Degree programme34Minors and transferring to a Master's programme34Study guide34The first year34The second and third year35Courses35Universidad Politécnica de Madrid36Naval Engineering

8、36University of StrathclydeBEng Hons Naval Architecture with Ocean Engineering OverviewNaval Architects and Marine Engineers deal with the worlds largest moving structures and most powerful vehicles from huge ships to sailing yachts, from fast ferries to offshore wind turbines and oil platforms

9、.As a Naval Architecture student, you will learn to predict the stability and safety of ships, as well as their strength, speed, powering and propulsion requirements. You will discover how to calculate the motions of ships and other floating structures in rough seas, and how to estimate their reliab

10、ility and safety in extreme conditions. All the courses offer the chance to take classes in specialist subjects such as Small Craft Design, Marine Engineering or Ocean Engineering.The Departments extensive laboratory facilities include the Kelvin Hydrodynamics Laboratory which houses the largest uni

11、versity test tank in the UK and is equipped with state-of-the-art instrumentation for a variety of model tests in calm water and in waves; a testing base for marine thermodynamic-related projects; and a wave/towing tank suitable for a range of tests and fluid control experiments.Course StructureOcea

12、n Engineering deals with the technical aspects of fixed and floating marine structures and systems related to harnessing ocean resources. These include offshore oil and gas and the rapidly-expanding area of ocean renewable energy, as well as other ocean resource activities such as subsea mining and

13、aquaculture. In addition to core Naval Architecture subjects, you will study a range of specialised Ocean Engineering subjects and subjects related to the design of novel ships and offshore structures such as risk management and reliability analysis, station-keeping and control and subsea engineerin

14、g.Our MEng/BEng courses have a common core on which the more specialised knowledge is built. All students in Years 1 and 2 follow this core so it is possible to change course if you wish. In the early years, you will study basic Engineering Science and the fundamentals of Naval Architecture, includi

15、ng buoyancy and floatation, stability, and ship types and terminology. As you progress through the course, you will study more specific Naval Architecture subjects, such as resistance and propulsion, ship structural analysis, ship design, marine engineering systems, as well as business and managemen

16、t subjects.In the later years, you will study more advanced subjects, and classes related to your chosen specialist area. You will also take further business and management classes. Throughout the course, classes are complemented by design project work that you will carry out both individually and i

17、n small groups. There is also a specialised individual project on a subject which interests you.Learning&teachingThe main methods of teaching are lectures, tutorials, laboratory and group design classes. You can expect an average of 20 hours of lectures, labs and tutorials per week, which you ar

18、e expected to supplement with private study. Self-study is vital as it develops the confidence to enable you to tackle unfamiliar problems, an essential skill for the professional engineer. Field trips are arranged throughout the teaching period to give students first-hand experience of current indu

19、strial activities in the marine sector.Individual and group projects form a major part of the course from first year. First-year students carry out a basic design, build and evaluate project. Second-year students work in teams on a more detailed design/build/test exercise as part of the Engineering

20、Applications class. Part of the third year Marine Design incorporates a rules based group design project. In fourth year students carry out a performance based group design project as well as their major individual project. External speakers and/or industrial support play an important part in group

21、and individual project work.Laboratory work is introduced from first year with introductory sessions covering fundamental aspects of hydrostatics and stability. In second year students take part in the design and build of a small scale racing yacht which combines the use of professional Naval Archit

22、ecture design software for hull design, Computer Aided Manufacture for hull generation combined with hands on practical skills and hydrodynamic testing. An intensive laboratory based class in third year presents experimental testing in a more formal manner in which students carry out a number of hyd

23、rodynamics, dynamics and marine engineering experimental projects. Fourth-year students have the opportunity to carry out a laboratory based individual project.Computer software is used to demonstrate the practical application of a students acquired theory and also give students exposure to current

24、engineering practice. The use of professional software to solve real engineering problems is introduced in first year and this theme is strongly reinforced throughout the subsequent years of study. Students gain exposure to software packages for stability, dynamics and simulation, FEA, hydrodynamics

25、, risk based design as well as other more specialised software packages.AssessmentEach teaching year has two semesters of 10 weeks of formal lectures, tutorials, laboratory and coursework assignments, industrial visits, class tests, two weeks of additional tutorials and/or project presentations, fol

26、lowed by revision classes, private study and examinations. Most assignments involve summative assessments, with associated tutorials for formative guidance. Group exercises, including presentations and peer assessment, are an important part of formative development.The main method of assessment is e

27、xaminations in January and May. Presentations, laboratory reports and other coursework are submitted and marked individually throughout the year.MEng Naval Architecture and Marine Engineering OverviewNaval Architects and Marine Engineers deal with the worlds largest moving structures and most p

28、owerful vehicles from huge ships to sailing yachts, from fast ferries to offshore wind turbines and oil platforms.As a Naval Architecture student, you will learn to predict the stability and safety of ships, as well as their strength, speed, powering and propulsion requirements. You will discover ho

29、w to calculate the motions of ships and other floating structures in rough seas, and how to estimate their reliability and safety in extreme conditions. All the courses offer the chance to take classes in specialist subjects such as Small Craft Design, Marine Engineering or Ocean Engineering.The Dep

30、artments extensive laboratory facilities include the Kelvin Hydrodynamics Laboratory which houses the largest university test tank in the UK and is equipped with state-of-the-art instrumentation for a variety of model tests in calm water and in waves; a testing base for marine thermodynamic-related

31、projects; and a wave/towing tank suitable for a range of tests and fluid control experiments.Course StructureMarine Engineering is the engineering speciality which addresses the design, construction, installation and operation of machinery and propulsion systems for ships and marine structures. In a

32、ddition to core Naval Architecture subjects, you will study a range of specialised Marine Engineering subjects such as control theory and practice, electrical systems, design of marine engines (diesel, diesel-electric and gas turbine), propeller and shafting systems, system design and simulation, gr

33、een technology and fuel cell technology.Our MEng/BEng courses have a common core on which the more specialised knowledge is built. All students in Years 1 and 2 follow this core so it is possible to change course if you wish. In the early years, you will study basic Engineering Science and the funda

34、mentals of Naval Architecture, including buoyancy and floatation, stability, and ship types and terminology. As you progress through the course, you will study more specific Naval Architecture subjects, such as resistance and propulsion, ship structural analysis, ship design, marine engineering syst

35、ems, as well as business and management subjects.In the later years, you will study more advanced subjects, and classes related to your chosen specialist area. You will also take further business and management classes. Throughout the course, classes are complemented by design project work that you

36、will carry out both individually and in small groups. There is also a specialised individual project on a subject which interests you.Learning&teachingThe main methods of teaching are lectures, tutorials, laboratory and group design classes. You can expect an average of 20 hours of lectures, lab

37、s and tutorials per week, which you are expected to supplement with private study. Self-study is vital as it develops the confidence to enable you to tackle unfamiliar problems, an essential skill for the professional engineer. Field trips are arranged throughout the teaching period to give students

38、 first-hand experience of current industrial activities in the marine sector.Individual and group projects form a major part of the course from first year. First year students carry out a basic design, build and evaluate project. Second-year students work in teams on a more detailed design/build/tes

39、t exercise as part of the Engineering Applications class. Part of the third year Marine Design incorporates a rules based group design project. In fourth year students carry out a performance based group design project as well as their major individual project. In fifth year MEng students carry out

40、a major, first principles based, group design project. External speakers and/or industrial support play an important part in group and individual project work.Laboratory work is introduced from first year with introductory sessions covering fundamental aspects of hydrostatics and stability. In secon

41、d-year students take part in the design and build of a small scale racing yacht which combines the use of professional Naval Architecture design software for hull design, Computer Aided Manufacture for hull generation combined with hands on practical skills and hydrodynamic testing. An intensive lab

42、oratory based class in third year presents experimental testing in a more formal manner in which students carry out a number of hydrodynamics, dynamics and marine engineering experimental projects. Fourth year students have the opportunity to carry out a laboratory based individual project. Further

43、experimental work is carried out in fifth year as part of the Marine Simulation class. Fifth year group design teams have access to the laboratory facilities.Computer software is used to demonstrate the practical application of a students acquired theory and also give students exposure to current en

44、gineering practice. The use of professional software to solve real engineering problems is introduced in first year and this theme is strongly reinforced throughout the subsequent years of study. Students gain exposure to software packages for stability, dynamics and simulation, FEA, hydrodynamics,

45、risk based design as well as other more specialised software packages.AssessmentEach teaching year has two semesters of 10 weeks of formal lectures, tutorials, laboratory and coursework assignments, industrial visits, class tests, two weeks of additional tutorials and/or project presentations, follo

46、wed by revision classes, private study and examinations.  Most assignments involve summative assessments, with associated tutorials for formative guidance. Group exercises, including presentations and peer assessment, are an important part of formative development.The main method of assessment

47、is examinations in January and May. Presentations, laboratory reports and other coursework are submitted and marked individually throughout the year.University of SouthamptonMEng Ship Science / Naval ArchitectureOverviewYears one and two are the same as for the MEng Ship Science(J641) and

48、common to all Ship Science themed programmes. Years three and four allow for specialisation in Naval Architecture. This course will enable you to specialise in core naval architecture subject areas such as resistance and propulsion, manoeuvring, hydrodynamics and offshore structures. Computing and c

49、omputer-aided design feature strongly throughout. The group design project in year four involves a detailed analytical and/or experimental study and the design of a marine vehicle or one of its major features.  In the past, projects have explored designs for marine renewable energy devices, aut

50、onomous underwater vehicles, commercial nuclear vessel design and a dry berthing facility for day sailing.Programme structureThe teaching is structured on a semester pattern. You study modules comprising 120 credits in each of Parts I (level C), II (level I) and III (level H), and 150 credits in Par

51、t IV (level M).There are two degree possibilities in the programme of study:Three years full-time, leading to a Bachelor of Engineering (BEng).Four years full-time, leading to a Master of Engineering (MEng) in one of several specialist themes.In addition there are the following exit points:Certifica

52、te of Higher education, following successful completion of Part I.Diploma of Higher education, following successful completion of Part II.Ordinary Degree of Bachelor of Engineering BEng (Ordinary), following successful completion of at least 300 credit points, including 60 points at level H.A Univer

53、sity credit is the equivalent of 10 notional study hours. Each module is a self-contained part of the programme of study and carries a credit rating. The duration of all the programmes may be extended by one year through enrolment on the Engineering Foundation Year.Typical course contentWhichever pr

54、ogramme you choose, you will study a number of core subjects during the first two years. These provide sound preparation for the final part of the degree. You will concentrate on the fundamentals of engineering and gain the skills and understanding required to use information technology in an engine

55、ering context.In Year 3, you will have the opportunity to specialise or retain a broad-based study path through a wide selection of subject modules. You will also undertake an individual project that usually takes the form of a design or research exercise and involves significant literature reviews,

56、 experimentation, mathematical modelling or computation, and the production of a formal report.In Years 3 and 4, students select options from discipline-specific core subjects such as advanced naval architecture and high performance craft. Students can also choose from more general engineering and n

57、on-discipline specific subjects such as finite element analysis, control, languages and industrial law.In Year 4, MEng students participate in a Group Design Project (GDP). These projects are often linked to current research activities or topics that have practical relevance to industry.Special Requ

58、irements - All CoursesVisits to industry and research establishments are organised for Part I and Part II candidates in the summer term. Candidates are required to attend the Part I Workshop Training Course unless exemption is given by the School.Candidates are required to attend the Part II course in Library Search Techniques. This is normally held after the Semester 2 examinations. Assignments set in this course will be formally assessed as part of their examination requirements.ModulusYear 1MATH1054Mathematics for Engineering and the EnvironmentThe aims of this module are to: