Online Master's Degree in Manufacturing

Find Online Masters Programs in Manufacturing 2017

Manufacturing

A masters refers to the completion of a graduate study program that prepares students to further their knowledge of a specific subject or advance their careers. The majority of masters are granted by state or public universities.

A Master in Manufacturing is concerned with the analysis of problems within areas of the manufacturing areas. It performs this analysis by using computer implementation, case studies or modelling techniques. Graduates will be able to perform in a variety of areas that have a manufacturing process.

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Master Advanced Manufacturing Processes for Aeronautical Structures (AMPAS)

Ecole Des Mines D’Albi-Carmaux | EMAC
Campus Full time 1 year September 2017 France Albi

The Advanced Master course AMPAS, is designed by Mines Albi and ISAE with the support of aeronautical industry partners. [+]

Best Online Masters in Manufacturing 2017. Master Advanced Manufacturing Processes for Aeronautical Structures (AMPAS) A booming industry After a short recession period, the Aeronautical industry market is facing a rapid and continuous increase worldwide as shown by the record breaking contracts recently signed by both Airbus and Boeing. These two industry leaders forecast an increase of close to 5% in activity over the next years and estimations indicate that the annual increase of large commercial airplanes will induce a doubling of the number of aircraft by 2030. Nearly sixty percent of the turnover is subcontracted all over the world and concerns mostly production and manufacturing activities. As a consequence most aeronautical subcontracting companies will have to increase their production rates but also to keep up to date with technological changes; moving from metallic processes toward composite materials processes. Moreover the aircraft manufacturers have changed their supply chain structure in the last years, and subcontractors are now required to manage more complex parts and to take over, on their own, the qualification processes. At the heart of Europes Aerospace Valley The Midi-Pyrénées is home to the global headquarters of Airbus and over 600 subcontracting businesses, employing more than 60,000 employees. The French space agency (CNES), as well as Thales and EADS Astrium are also present in the area along with their lot of subcontractors. The Ecole des Mines d’Albi and Institut Supérieur de l’Aéronautique et de l’Espace (ISAE), have both a proven track record of leading research and working alongside industrial partners in the aeronautics industry. This master program is accredited by the French “Conference des Grandes Ecoles” A formation tailored to the need of the industry The Advanced Master course AMPAS, is designed by Mines Albi and ISAE with the support of aeronautical industry partners. It will give a specialization to master level students allowing them to take over high level responsibilities in airframe structure manufacturing plants. It is especially well suited to students who have followed general studies in mechanical engineering, material science or equivalent and who would like to gain a major chance to be recruited by aeronautical industry. To reach this goal, AMPAS master students will develop: general knowledge of flight dynamics constrains and airframe design knowledge and understanding of the airframe materials and processes and their qualification constrains knowledge, understanding and practice of the prevalent processes for structural applications with either metallic or fiber reinforced thermoset composites materials ability to use state of the art simulation tools for definition and optimization of metallic sheet forming and RTM/infusion process knowledge of the aeronautical supply chain structure and their communication rules understanding of the aeronautic dedicated quality and management requirements knowledge and practice of lean manufacturing tools ability to undertake manufacturing projects in an international team environment ability to communicate with written reports and by oral presentation Lecturers Professoral staff form Ecole des Mines Albi and ISAE (Institut Supérieur de l'Aeronautique) and more generally from University of Toulouse Experts form Aeronautical Insdustry, especially from AIRBUS and supply chain Experts from certification, quality, supply chain organization and management Requirements Applicants must have a Master degree, or an equivalent degree in science or engineering, or a bachelor degree with 3 years of professional experience at least. English Language Requirements IELTS band: 6 TOEFL paper-based test score : 550 TOEFL iBT® test: 79 Contents A balance of theoretical learning and practical experience: The course consists of 75 credits mixing academic teaching and professional experience. First semester: academic term of 450h and 45 credits, provided by permanent professors of Mines Albi and ISAE and expert practitioners from aerospace industry to bring current knowledge and experience. The teaching, balancing academic lessons with more applied practice. Second semester: Professional thesis in the aeronautical industry or in an academic research lab in collaboration with aeronautical industrial partners, in France or abroad. The duration is from 5 to 6 months and corresponds to 30 credits. Students are supervised by a tutor from the host organization and from Mines Albi or ISAE. Thesis is concluded by the preparation of a final report and an oral dissertation in front of a jury. Syllabus The academic course consists of 450 hours of taught modules aiming to provide a deep knowledge of the three main material families used in airframe structures (i.e. aluminum, titanium and long fiber reinforced polymer composites) as well as their related forming routes relevant to aeronautical industries. It is also devoted to gain knowledge in aircraft architecture, on aeronautical supply chain specificities, lean manufacturing and quality management required to be able to take over technical and organizational responsibilities in industry. A team project (100 hours) will demonstrate the ability to address an aeronautical part processing problem following the theoretical and professional skills. In more details: 1. Aircraft, material and process basic scientific knowledge Aircraft General Knowledge Flight Dynamic Structure and Airframe Design Aeronautical materials and processes Aluminium and titanium alloys Epoxy and thermoplastic composites Assembly processes Material and processes qualification NDT and shape control techniques NDT for metallic and composite materials Optical techniques for assembly aid Computer Aided Design 2. Composite structure forming and machining Processes Physical phenomena description and modeling related to epoxy based manufacturing Raw material and composite quality control LCM/RTM processes Autoclave Vacuum Bagging (monolithic - sandwich) processes Composite material trimming, drilling and assembly RTM/Infusion Simulation 3. Metallic structure forming and machining processes Material behaviour and mechanical model Cold and hot sheet forming processes Surface treatments Metallic material machining Sheet forming simulation 4. Industrial Organization and Management Supply chain structure and organization Materials management and Lean manufacturing Supply chain improvement and collaborative processes Quality management and tools 5. Integrated Team Project 6. Internship and Professional Thesis (2nd semester) [-]

Masters in Leather Engineering - IN FRENCH

ITECH Lyon
Campus Full time 3 years France

ITECH leather engineers work for large chemistry product firms, in tanneries and taweries and for the users: leather shops, shoe makers... [+]

ITECH is the only institution in world that offers an engineering degree in leather that suits the industry in all its aspects. The leather engineer’s job involves the transformation of raw skin into leather by supplying it with main parts of its added value. Practical workshops are essential and dominant in this major. There’re many qualities that are required: observation, touch, practical knowledge, rigor, esthetical. ITECH leather engineers work for large chemistry product firms, in tanneries and taweries and for the users: leather shops, shoe makers... The leather market spreads worldwide and also requires extreme mobility, polyvalence and adaptability. Admission for Students outside France 1st year admission: Graduate studies in chemistry (Bachelor’s degree or equivalent , 180 ECTS) A satisfying level in French: B2 CERF + interview with ITECH 2nd year admission: 1 year of postgraduate studies completed (M1 or equivalent, 240 ECTS) How to apply? Visit and register at inscription.itech.fr (for EU students) Or Apply through Campus France site (CEF procedures): For countries which do not have CEF procedures with France, you must do an Application for Preliminary Admission (DAP) to the cultural service of the French embassy in your country of residence. Please visit www.campusfrance.org/en/applying-other-countries for details. Tuition fees Tuition fees for the French Section are 6 500€/year. Hands on training ITECH is adamant in supplying students with a strong professional experience. On top of a multidisciplinary teaching, the institute adds a 10 month minimum of mandatory internships in companies for the regular status students. End of 1st year: International experience - minimum 6 weeks This international experience is prepared in advance in terms of an intercultural approach and the expectations regarding the content of the report are fully defined. This is an individual review of each student’s experience and acts as a basis for reflection during the intercultural lessons the following term. End of 2nd year: Engineering placement - minimum 8 weeks Practical application with privileged trainee status allows students to come face to face with the realities of corporate life and become acquainted with companies’ material, economic and human requirements. End of 3rd year: Final year project - maximum 6 months This is a project generally entrusted to young engineers. Students demonstrate that they are capable of acting autonomously and tackling complex subjects in situations that can, at times, prove complex. The project involves a minimum 5-month placement with a company or laboratory either in France or abroad. The Region Lyon is located in the south-east of France, on the confluence of the Rhône and the Saône Rivers. It stands on a geographical crossroads, to the North of the natural corridor of the Rhône valley (which stretches from Lyon to Marseille). With the Lyon-Saint Exupéry international airport and three TGV high-speed train stations, Lyon is connected to all major European cities and the world! Lyon is only 2 hours by TGV to Paris and 1hr40 to Marseille and the Mediterranean. If it's mountains you prefer, the Alps are a mere 90 minutes away by car, the Massif Central only 30 minutes away. Historically, Lyon is an industrial city and therefore houses many petrochemical industries along the Saône and Rhône Rivers, in the so-called ‘chemistry corridor’. Lyon is also the city with the second largest number of students in France, with three universities and many engineering schools. In terms of its population, it’s the 3rd biggest city in France, with over 470,000 inhabitants, and the second largest agglomeration after Paris (2 million inhabitants). [-]

MEng in Mechanical and Manufacturing Engineering

Dublin City University
Campus Full time 1 year September 2017 Ireland Dublin

This Masters programme allows students to specialise in the widely established area of Mechanical and Manufacturing Engineering or to widen their knowledge from their undergraduate studies. [+]

Best Online Masters in Manufacturing 2017. Introduction This Masters programme allows students to specialise in the widely established area of Mechanical and Manufacturing Engineering or to widen their knowledge from their undergraduate studies. It enables graduates to apply their knowledge using computer–based technology to solve mechanical and manufacturing engineering problems. This programme introduces the use of advanced Computer Aided Engineering tools and, by experiencing these advanced techniques and software, the graduate will gain a vital edge. It allows the candidate to keep up with the rapidly changing manufacturing and design sectors. In addition, students can opt for a specialist Major in Sustainable Systems/Energy, or Biomedical Engineering. Who is eligible? To apply for this programme candidates must have an Honours degree in Mechanical and/or Manufacturing Engineering. Candidates whose first language is not English will be required to submit evidence of an English Language qualification. For more information on entry requirements please consult our website. Choice of Majors Sustainable Systems/Energy - There is a growing international market for Engineers in sustainable energy and development, eco– innovation, resource efficiency and clean–tech sectors. There are lots of career opportunities in the growing fields of Energy/Renewable Energy (wind, wave, solar, biomass etc.); a national priority area for Ireland. Biomedical Engineering - This discipline integrates the necessary aspects of biology and medicine with the technical engineering aspects required to engineer medical devices. The world of medicine is evolving and expanding rapidly, with new treatments and new diseases appearing all the time. As Ireland is a major player in Bioengineering, this Major provides graduates with specialisms required by industry. Structure The MEng in Mechanical and Manufacturing Engineering is designed to be completed in one calendar year of full-time study. It consists of two (full-time) taught semesters, followed by a practical project, completed between May and early September. The next intake for this programme will be September 2017. DCU offers a number of scholarships to international students each year. To be eligible to apply for a scholarship from DCU you must first apply to and receive an offer for a DCU Masters programme. Apply online for September 2017 entry at www.pac.ie/dcu using the PAC code DC814 [-]

MEng in Welding Engineering

University of the Witwatersrand
Campus Full time 1 year February 2017 South Africa Johannesburg

Wits University offers the International Institute of Welding course leading to the IWE ( International Welding Engineer -[BScEng graduates]) and IWT ( International Welding Technologist [BTech graduates]). Wits University is an Approved Training Body (ATB) for the International Institute of Welding (IIW). Successful completion of the courses (60% min/each module and a 95% attendance record) entitles the candidate to apply for IIW registration. [+]

Wits University offers the International Institute of Welding course leading to the IWE ( International Welding Engineer -[BScEng graduates]) and IWT ( International Welding Technologist [BTech graduates]). Wits University is an Approved Training Body (ATB) for the International Institute of Welding (IIW). Successful completion of the courses (60% min/each module and a 95% attendance record) entitles the candidate to apply for IIW registration. Benefits of the programme The intent is to equip candidates for a career in the welding industry, this implying an understanding of the practice of welding engineering underpinned by sound science. Curriculum Outline / Modules taught The MEng in Welding Wits is made up of 12 courses divided into four main modules. The modules are welding processes, welding metallurgy, welded joint design and fabrication, and applications and case studies. Closing dates Whilst late entries can be considered the desirable closing date for those completing the whole course is mid February. Whilst those who complete individual stand alone courses can register through the year, if individual courses are taken as part of, say a GDE, the February registration applies. Note: The GDE/ MEng qualifications will be replaced by the PGD/MScEng qualifications in 2017. Whislt the structure will change the intent is that the programme continue to offer the IWE/IWT curriculum. [-]

Master in Global Production Engineering and Management

Vietnamese-German University
Campus Full time 2 years September 2017 Vietnam Ho Chi Minh City

Global Production Engineering and Management is a full-time 2-year Master Program offered at VGU by the Technische Universität Berlin. [+]

Best Online Masters in Manufacturing 2017.

Globalization and technology development advance rapidly. In a global market companies have to balance the ability to create and design innovative solutions as well as the ability to exploit them. Industry-based companies demand strategy-oriented personnel with a solid technological basis on the one side and an entrepreneurial attitude on the other. To meet the growing challenges and opportunities in a globalized economy, the need for leaders with international perspective increases

Rather than focusing on business administration, Global Production Engineering (GPE) enables engineers to create systematic technological innovation combined with efficient and effective industrial business management.... [-]


Master in Product Development and Materials Engineering

Jönköping University
Campus Full time 2 years September 2017 Sweden Jönköping

As competition between companies is getting tougher as the number of products on the market increases, many are realising the importance of product development and material knowledge as a competitive means. This programme covers the entire product development process, from conceptual engineering design to materials and manufacturing processes. [+]

As competition between companies is getting tougher as the number of products on the market increases, many are realising the importance of product development and material knowledge as a competitive means. This programme covers the entire product development process, from conceptual engineering design to materials and manufacturing processes. The work of engineers within product development is creative and offers a great deal of variety. This Master's programme (two years) qualifies students for positions with the manufacturers and suppliers that develop and produce components or as consultants. Emphasis is placed on design and construction of technical components and products in regards to customer demands, use, producibility and production methods. Vehicles, household appliances, medical equipment and certain sporting goods are all examples of products made up of complex components. Making complex things simpler The steady increase in the use of computer support makes possible new methods, which are parallel to the entire product development process. With the help of advanced computer tools in design and construction, real and virtual prototypes can be produced much faster, and the time needed for development can be shortened. In addition, a product can be studied and tested at an early stage of product development for its design, usability, durability, safety and producibility. Important aspects of work with the development of components and products include the analysis of function and performance, the choice of materials and the methods of production. This programme gives an understanding of the theory behind and the practical use of the computer based tools needed for these tasks. Industry contacts and guest speakers Some of the courses include project work. Students can, in smaller groups, analyse and make suggestions regarding real-life problems taken straight from the industry. Guest speakers from the field also take part in instruction. A thesis at the end of the programme helps students apply their theoretical knowledge and gain insight as to the research and development within the industry and the university. Extensive knowledge about materials is also acquired. The School of Engineering has well-equipped research labs for materials engineering and computer simulation. Next generation of engineers The School of Engineering, Jönköping University, is a member of the prestigious collaborative between leading engineering schools worldwide - the CDIO Initiative™. The CDIO Initiative is an innovative educational framework to conceive and develop a new vision of engineering education and for producing the next generation of engineers. The programme qualifies you for positions with manufacturers and suppliers that develop and produce components, or as consultants. Courses within the programme NB Preliminary list of courses Year 1 Industrial Product Realisation: Process - Methods - Leadership 9 Credits Materials And Design 6 Credits Non-Linear Finite Element Analysis 9 Credits Elective Course:Advanced CAD 6 Credits Elective Course:Multivariable Calculus 6 Credits The course multivariable calculus is compulsory to students who have not studied this course during their bachelor studies. Computer Programming For Design Automation 6 Credits Functional Materials And Surfaces 6 Credits Integrated Product Development 12 Credits Optimisation Driven Design 6 Credits Year 2 Advanced Materials Technology 6 Credits Computer Supported Engineering Design 9 Credits Industrial Placement 9 Credits Modelling And Simulation Of Casting 6 Credits Final Project Thesis, Master 30 Credits Facts Credits: 120,0 credits Level: Master's Rate of study: Full-time Place of study: Campus-based Language: English Start date: Autumn 2016 Requirements: The applicant must hold the minimum of a bachelor's degree (ie. the equivalent of 180 ECTS credits at an accredited university) with at least 90 credits in mechanical engineering or equivalent. The bachelor's degree should comprise a minimum of 21 ECTS credits in mathematics. Proof of English profiency is required. [-]

Master of Engineering in Microelectronics Manufacturing Engineering

Rochester Institute of Technology (RIT)
Campus or Online Full time Part time 2 years September 2017 USA Rochester + 1 more

The master of engineering degree in microelectronics manufacturing engineering provides a broad-based education to students with a bachelor’s degree in traditional engineering or science disciplines who are interested in a career in the semiconductor industry... [+]

Best Online Masters in Manufacturing 2017. Master of Engineering in Microelectronics Manufacturing Engineering The master of engineering degree in microelectronics manufacturing engineering provides a broad-based education to students with a bachelor’s degree in traditional engineering or science disciplines who are interested in a career in the semiconductor industry. Graduates of the program will: design and understand a sequence of processing steps to fabricate a solid state device to meet a set of target parameters; analyze experimental electrical data from a solid state device to extract performance parameters used in the device design; understand current lithographic materials, processes, and systems to meet imaging and device patterning requirements; understand the relevance of a process or device to current manufacturing practices; perform in a microelectronic manufacturing environment in an area of specialization, such as device engineering, circuit design, lithography, materials and processes, yield enhancement, and manufacturing. Program outcomesThe MS program in microelectronics manufacturing engineering has a number of outcomes for its students:... [-]

Masters in Manufacturing Engineering

Bradley University
Campus Full time Part time September 2017 USA Peoria

The master’s of manufacturing engineering program at Bradley University provides students with professional robust design and continuous improvement principles. The program gives students the ability to improve integrated systems, optimize manufacturing processes, adopt state-of-the-art materials, and produce superior quality products at minimal cost. By working closely with both constituencies and students, the department combines theoretical learning with hands-on application to keep students – and the organizations they benefit – globally competitive in today’s economy. [+]

Program Mission The master’s of manufacturing engineering program at Bradley University provides students with professional robust design and continuous improvement principles. The program gives students the ability to improve integrated systems, optimize manufacturing processes, adopt state-of-the-art materials, and produce superior quality products at minimal cost. By working closely with both constituencies and students, the department combines theoretical learning with hands-on application to keep students – and the organizations they benefit – globally competitive in today’s economy. Role of Manufacturing Engineers Manufacturing engineers (MfE) are the intermediaries between consumers and the production floor. As the key personnel who understand the relationship between the Voices of the Customer (VOC) and the Voices of the Products (VOP), their leadership and management skills are critical in determining optimal processes, minimal production costs, superior products and customer satisfaction. Further, MfEs enhance production by eliminating waste; establishing standardized operations; creating safe, green working environments; and providing training and development to the workforce. The manufacturing engineering (MSMfE) master’s program at Bradley University is designed to broaden the career paths of our students in manufacturing sectors. This sector is comprised of all organizations engaged in the mechanical, physical, or chemical transformation of materials, substances, or components into new products. A list of possible manufacturing engineering careers for master’s degree holders includes, but is not limited to, the following: Manufacturing engineers at the Caterpillar Technical Center develop new processes that can be used in the development of new products. By optimizing process maps, they ensure that the best procedures are developed and implemented. Manufacturing engineers at 3M support the production facility’s efforts to increase product quality and reliability through constant reassessment and refinement of the manufacturing process. In the R&D department, they also develop manufacturing methodologies and equipment for products and subassemblies. Manufacturing engineers at General Mills develop automated production lines integrated with on-line quality control and safety inspection to guarantee that the cereals, snacks, and other such consumables they produce are safe, nutritional, and profitable products. Manufacturing engineers at Pella Cooperation facilitate Product-Process-Production (PPP) development teams to design products while taking into account merchandise functions, production processes, and efficient assembly practices. These efforts result in organized one-piece-flow manufacturing systems that minimize floor space to meet delivery deadlines. Manufacturing engineers at Toyota Motors Manufacturing Kentucky Inc. build pokayoke (defect prevention) devices to ensure smooth operations in the assembly line. By using PLC and sensor-related knowledge, they create damage prevention devices that automatically halt the line when errors are detected. They also create ergonomic tools to ensure the safety and efficiency of operators. Manufacturing engineers at Ecolite Manufacturing West (Moreno Valley, CA) develop, evaluate, and improve manufacturing methods using their design skills and familiarity with materials, fabrication processes, tool and production equipment capabilities, assembly methods, and quality assurance. Their work also includes applying lean manufacturing principles to develop efficient assembly equipment and operations. Educational Development for Future Success MSMfE at Bradley not only provides a self-constructed program of study for each student based on his or her career interests, but also encourages graduate students to conduct research projects to expand their knowledge in a specific field. The independent research and project management skills gained through this type of training are key core competencies of engineers in any organization. MSMfE students will be encouraged to begin research projects early in their academic training in order to foster interactions between faculty and students and increase chances for industry or federal agency-funded projects. Faculty Faculty in the MSMfE program share core values to provide the best curriculum and classroom experience possible. Our faculty of varying academic experiences, and areas of expertise provide a wide range of research opportunities to meet specific student needs, allowing them to not only understand the theory but also grow through industrial or practical projects. The faculty education background can be found here. Expert Research Support Two full-time technicians with mechanical and computer networking expertise aid the Department of Industrial & Manufacturing Engineering & Technology. They support the MSIE faculty and graduate students with a multitude of project needs, such as creating fixtures for prototype developments, assisting in networking, and preparing specimens for experiments. Degree Requirements The program offers students three options: thesis, research project, and a courses only option. For more detailed information on these options, please refer to the following document. (Rules for Thesis and Project Options) The MS degree has a minimum requirement of 30 semester hours with a minimum grade point average of 3.00 for degree completion. Credit hours must be fulfilled as follows: A. Core Courses – 3 Credit hours (one from the following list) IME 511 Engineering Statistical Methods 3 IME 512 Design and Analysis of Experiments 3 B. Thesis (6 credit hrs), Research project (3 credit hrs) – not required for all-course option Thesis Option IME 699 Thesis Work 6 Research-Project Option IME 691 Research 3 Both thesis and project options should lead to a scholarly publication which must demonstrate comprehensive and in-depth knowledge of a topic in a concentration. It should be suitable for submission to a refereed publication acceptable to the Program of Study (POS) committee. A thesis involves more extensive and in-depth research than a research project. Responding to input received from industry and our alumni, the masters of Manufacturing engineering program (MSMFE) has been modified to allow students to select from one of the following concentrations: 1) Production Engineering Concentration 2) Manufacturing Management Concentration Rules for Thesis and Project Options This document provides definitions and rules relative to research-projects, theses and comprehensive exams to be completed by students in the graduate programs in the IMET Department. C. Concentration courses (min. 15 credit hours) Production Engineering Concentration (1) IME 531 Polymer and Ceramic Materials and Manufacturing Or IME 533 Composite Materials and Manufacturing 3 (2) IME 541 Advanced Forming Processes 3 (3) IME 543 Advanced Material Removals Processes Or IME 547 Advanced Joining and Fabrication 3 (4) IME 553 Advanced CAM 3 (5) IME 555 Computer Integrated Manufacturing System 3 (6) IME 590 Geometric Modeling Or IME 592 Tribology 3 (7) IME 595 DFM & Tool Design 3 Manufacturing Management Concentration (1) IME 501 Engineering Economy and Cost Engineering 3 (2) IME 522 Manufacturing Quality Control 3 (3) IME 524 Six Sigma Theory and Methodologies 3 (4) IME 555 Computer Integrated Manufacturing Systems 3 (5) IME 581 Lean Manufacturing System Design 3 (6) IME 586 Advanced Logistical Supply Chain Systems 3 (7) IME 566 Advanced Facility Planning 3 (8) BMA 602 Organizational Behavior 3 D. Elective courses The remainder of credits must be taken from the list below: a. Any 500-600 level course(s) offered in the IMET Department b. Any other graduate level course(s) in the University with consent of the project/thesis adviser [-]

Master of Engineering (Mechanical and Manufacturing Engineering)

RMIT University
Campus Full time 2 years January 2017 Australia Melbourne

Our research is supported by state of the art facilities, including the Advanced Manufacturing Precinct. We have experienced supervisors and extensive... [+]

Master of Engineering (Mechanical and Manufacturing Engineering)

Use your advanced engineering skills to contribute to our applied industry focused mechanical and manufacturing research projects.Our experienced engineering researchers have achieved significant successes across application areas and industry sectors.Through collaboration with our own institutes and centres we produce creative solutions to existing and emerging industry-applicable engineering problems.Our research is supported by state of the art facilities, including the Advanced Manufacturing Precinct.We have experienced supervisors and extensive and advanced research facilities to support your individual research project in the following areas:Mechanical Engineering:... [-]


Master of Engineering (Manufacturing)

RMIT University
Campus Full time 2 years January 2017 Australia Melbourne

In this program, you'll gain knowledge and skills to lead change, adopt new technologies and implement new operating practices in manufacturing businesses... [+]

Master of Engineering (Manufacturing)

Gain knowledge and skills to lead change, adopt new technologies and implement new operating practices in manufacturing businesses.Right now, worldwide, manufacturing companies are undergoing dramatic change. The combination of new technology, customer expectations and global competition is forcing new approaches to automation, factory design and manufacturing systems.As the pace of change accelerates, it creates demand for trained professionals who can strategically apply new technologies and modes of manufacturing in industry.Manufacturing companies already use computerised information systems, but there is need to achieve true systems integration through the adoption of 'whole enterprise' modelling approaches. Production machines and processes are increasingly under computer/microprocessor control, and this requires more sophisticated approaches to maintenance management.... [-]


Master in Manufacturing Engineering

University West
Campus Full time 1 - 1 year September 2017 Sweden Trollhättan

The current globalisation offers many opportunities for work in international companies and abroad. It also means that competition is stiffer and that it is importan [+]

Master in Manufacturing Engineering

The current globalization offers many opportunities for work in international companies and abroad. It also means that competition is stiffer and that it is important to be adequately educated. Manufacturing engineering is one of the strongest areas of University West and in this one-year master programme, you have the possibility to improve your CV, for a career in the manufacturing industry, global corporations, or for an academic career. The education offers both specialized technological knowledge as well as breadth within manucfacturing engineering, which is a necessety for leading positions in the industry.

 ... [-]


Master of Management and Manufacturing

Kellogg School of Management at Northwestern University
Campus Full time 2 years September 2017 USA Evanston

Today's global marketplace requires a new type of manager-leader: one able to fuse strategic business practices with cutting-edge technology. MMM is a two-year dual degree program of the Kellogg School of Management and the McCormick School of Engineering at Northwestern University [+]

Today's global marketplace requires a new type of manager-leader: one able to fuse strategic business practices with cutting-edge technology. The Master of Management and Manufacturing Program offers an unparalleled opportunity to master these critical skills and prepare for a lifetime of professional achievement. MMM is a two-year dual degree program of the Kellogg School of Management and the McCormick School of Engineering at Northwestern University.The MMM program offers many advantages:

The opportunity to earn two degrees, with one set of curricular requirements, in just two years: the Master of Business Administration degree from the Kellogg School of Management and the Master of Engineering Management degree from the Robert R. McCormick School of Engineering and Applied Science. A flexible curriculum that allows students to take a wide array of courses in areas most suited to their career goals, including marketing, operations, finance and entrepreneurship. A hands-on, team-based approach to learning that applies theory to real-world challenges. A shared student experience with peers in the Kellogg School \\\'s full-time MBA program, including extracurricular and leadership opportunities. Access to world-class experts and facilities in nanotechnology, biotechnology and other technical disciplines with significant business implications. Outstanding career opportunities in a wide range of functions and industries, including general management, operations and production, finance, product development, business development, marketing and strategic planning. ... [-]