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Space production technological equipment for mechanical engineering

Space production technological equipment for mechanical engineering

Mechanical Program Overview Areas of study: Thermal science, fluid mechanics, manufacturing and controls, material science engineering, applied mechanics, productions and operations research Option: Aerospace Degree awarded: Bachelor of Science in Engineering Mechanical Mechanical engineers use the principles of mechanics and energy to design machines and processes. Many mechanical engineers work in energy and environmental specialties such as building systems, engine design, oil refining, mining, and air quality control, and pollution control processes. Others are involved in the automotive, manufacturing, materials science and biomechanics areas. Mechanical engineers can specialize in the aerospace area, and work in the design and development of technology for aviation and space exploration. The University of Manitoba's Mechanical Engineering program is ranked 5th among universities in Canada, and 15th in comparison with other mechanical engineering programs in North America.

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Working as a Mechanical Engineer

Students will have a choice of specialisation in Design or Mechatronics. Under the Design specialisation, students will learn the concepts of digital manufacturing and design through modules in additive engineering, advanced materials technology, mechanical design and microelectronics for engineering products.

Students in the Mechatronics specialisation will learn the special skill sets in IIoT used for automation and robotics, unmanned systems, co-bot design and build, as well as machine learning.

Graduates from this programme will be equipped with sound principles in mechanical design or mechatronics as well as deep knowledge in digitalisation. They will be practice-oriented and innovative individuals with the right skill sets for the future digital economy. Subject to approval, diploma applicants may be granted module exemptions, based on the modules taken during their diploma. Academic Calendar. Download Cluster Brochure.

View Cluster Brochure in Flipbook. Degree Classification. This course starts with complex numbers, vectors. This is followed by the basic concepts of limits, differentiation and integration, as well as the differential and integral calculus. An introduction to the concept of partial fractions, Fourier series, Euler's formula, Laplace transform and other numerical methods will prepare the students for other modules in Year 1.

Understanding engineering designs is a basic skill expected of all engineers. It is essential because graphics communication and documentation using 2-D drawings and 3-D computer models are a universal means of communicating a design idea clearly, and allowing the idea to be converted into physical products.

This module is for students in their first year of studies. Student progress shall be assessed through drawing assessment and assignment, final design project, presentations and final report.

This module is an introduction to the historical and social context of computing, Basic concepts in programming Data types, Control structures, Functions, Arrays, pointers, Files , Running, Testing and Debugging scripts and programs, Overview of Programming paradigms. Programming concepts are demonstrated in a variety of languages and practised in a standard programming language C.

The module will also introduce students the best practices in secure coding such as input validation and data sanitization, and issues such as integer exploits and buffer overflows. This course provides students with the ability to apply the principles of engineering mechanics to determine elastic behaviour of members and components subjected to bending moment, shear force, axial force and torque, including elastic deflections of beams statically determinate and statically indeterminate and torsion of circular and thin-walled sections.

Behaviour of beams is also extended to simple cases of plastic bending behaviour. This module is intended for students with no prior knowledge in electronics and circuits, and can be taken by any student interested in fundamental skill sets in electronic circuits.

Specifically, the course focuses on developing a basic understanding of the fundamentals and principles of analogue circuits. A series of lectures and hands-on laboratory session that deliver brief introductions to tools and techniques for embedded system solution and key concepts in Internet of Things. This module introduces fundamental concepts like embedded programming, sensors and actuators, mobile application development and IoT implementations to help students relate to the digital world and to serve as foundation for future Big Data Analytic application.

This is followed by the solution of series and ordinary differential equations, operations of functions with multiple variables, linear algebra, partial differentiation. This module introduces students to modelling and analysis of dynamic systems, with particular emphasis on free and forced oscillations, and investigation of the system response.

Deriving the solution of the resulting differential equations and the application to simple vibration problems. The module aims to introduce students to the problems of automatic control, with practical illustrations, to provide a basic understanding of techniques used to model engineering systems and to allow students to gain a physical understanding of the factors influencing the steady-state and dynamic response of practical systems.

The module also provides an understanding of the time-domain and frequency-domain methods of analysis of control systems, an understanding of the properties of proportional, integral and derivative controllers and to allow students to gain experience of real closed-loop control systems and to learn about analysis methods using computer-based techniques.

The module will introduce materials properties and their selection in mechanical design, joining processes including welding and adhesive bonding, and forming processes for metallic and polymeric materials. This module focuses on the principles and applications of measurement, sensing technologies and signal processing. It is intended as a follow-on module from Fundamentals of Electronics and Circuits 1.

Students will be taught concepts of measurement uncertainty and errors, key principles, limitations and applications of a wide range of sensors. The course also aims to teach students the basic concepts of signals and linear time-invariant LTI systems, and how to represent and analyse them in both time and frequency domains.

In addition, students will be taught the principles of analogue-to-digital and digital-to-analogue conversions, and the requirements and their impact on the sensors and signals. This module aims to help you develop such abilities through academic essay writing, technical report writing, reflective writing, small group discussions, oral presenting and other learning activities.

For the principle instructional focus of the course, a project-based approach is used that requires teams of students to explore authentic engineering problems and develop viable solutions within real-world contexts.

Within the module, you will read discipline-specific articles, do writing assignments and a project with an engineering focus, and interview engineers or related experts, thus facilitating greater acquaintance with the field. This course covers statistics and probability, in which the calculation of mean, median, standard deviation, quartiles, percentiles and interquartile range will be covered.

Cumulative frequency diagrams, as well as box-and-whiskers-plot will be covered. This module develops the principles of stress and strain in three dimensions and illustrates the 2D plane stress and plane strain states as special cases of the 3D scenario.

Stress and strain transformations in 3D and 2D are studied and special stresses and strains such as principal stresses and strains in 3D etc. Equilibrium, compatibility and constitutive relationships are developed. Practical stress analysis scenarios such as in members undergoing combined bending and torsion and in pressure vessels. Particular attention is given to fracture mechanics and fatigue life assessment.

Thermodynamics is an exciting and fascinating subject that deals with energy and energy interactions. The module introduces the concepts of heat, work, efficiency and property diagrams of pure substance while discussing the 1st law of thermodynamics. The ideal-gas equation of state is introduced for ideal gases while real gases are described by other polytropic models. This module then aims to provide students with understanding of the application of thermal energy conversion using thermodynamic principles.

Students will learn about steam and refrigeration cycles using 2nd law of thermodynamics. In heat transfer, three main mechanisms of heat flow will be discussed; conduction, convection and radiation.

There are two modes of convection, namely natural and forced convection, where some convection correlations are derived to demonstrate and allow appreciation of its respective empirical convection heat transfer coefficient in real world.

Lastly, the radiation topic will cover basic concepts such as reflection, absorption, transmission and emission. The module will also provide the student with an understanding of heat exchangers and how such items of equipment are designed.

This module introduces the theory and solution procedure of the underlying finite element method FEM for planar and 3D linear elastic problems as well as heat transfer analyses.

The module also focuses on the practical application of FEM in engineering mechanics using commercial FEA software by providing professional guidelines on modelling, mesh generation and validation of the numerical results.

During practical lab sessions the students get basic instructions on how to use a popular commercial FEA software package to analyse the stresses in a 3D-printed part and validate the results against experimental data and simplified analytical models. The students finally get to demonstrate their gained FEA skills during individual projects working on more complex 3D geometries to analyse and improve the structural properties of provided design.

The module comprises three main components: - Job search — takes students through the entire process of job search; - Written communication — introduces students you to good practices in written workplace communication; and - Oral communication — gives students opportunities to hone their speaking skills in various work-related oral activities.

This module develops the students understanding of Availability, Reliability, Maintainability thereby enhancing the students' ability to evaluate design proposals from a number of related viewpoints. In addition, this module illustrates and develops an understanding of robust design from functional performance and manufacture viewpoints, and exposes students to the discipline involved in researching a technical area and producing a report and presentation.

The course serves as a foundation to introduce students to the concepts of Industrial Internet of Things as the key driver to integrating complex physical machines with networked sensors and software. It provides the foundation understanding of the key concepts such as IIOT architecture, state-of-the-art IoT protocols and standards at different levels, including devices, gateway and cloud. Students will also be exposed to different wireless technologies that enable pervasive and ubiquitous access of the sensed data.

This will lead them to understand the importance of foundation of data analytics on which applications can leverage to build smart applications and services. This module focuses on the implementation and delivery of an integrated engineering solution in the following specialised areas:.

Students will apply an engineering design process which includes steps such as empathy, problem definition, concept generation, reviewing the conceptual system design, breaking down the system design into component design, prototyping at various stages of design, and validation of design, to propose a feasible engineering solution to a given problem. Knowledge and application of relevant engineering standards will guide students to providing a sound engineering solution.

Students will work in teams and will be provided with support and resources to work independently in clarifying and prototyping their ideas to deliver an appropriate proposal. Students are not required to deliver a fully working system but their prototypes should be of sufficient resolution and with sound engineering principles, to demonstrate critical components of their solution. Ample opportunity for team work, discussions, critique and pitching is to be expected. Assessment will be through continuous assessment, peer review, presentations and reports.

This module aims to introduce advanced concepts of kinematic and dynamic modelling and analysis of mechanisms and machines, including linkage mechanisms and cam mechanisms, reciprocating and rotating machinery. Students will learn in depth core mechanical engineering concepts by integrating and applying contemporary analytical, computational and experimental methods.

It relates kinematics and dynamics of mechanisms and machines to their design and allows you to relate theory and practice using a problem-based approach. This project based module introduces the student to a range of modern methods and techniques supporting industrial product design activity.

The module provides additional design practice and engineering skills in terms of product development, design process, engineering evaluation, and documentation for the design of mechanical parts and components within engineering systems.

This course provides a grounding in the fundamental methods of fluid mechanics in both static and dynamic situations. It also introduces general principles such as dimensional analysis, which are widely applicable in engineering. Additive Engineering AE is a disruptive technology that is fundamentally distinct from conventional manufacturing technologies.

AE spans the complete product life-cycle, from concept-stage design to service part fulfilment. This module provides a holistic understanding of the concept and fundamentals of AE. It covers the principles, methodology and usage of various Additive Manufacturing systems, along with the understanding of pre- and post-processing of AE products.

Students will carry out a hands-on design and manufacturing project. This is an intensive 3-week group design project where students will take as an overseas immersion programme OIP at UofG. The project-based module introduces the student to a range of modern methods and techniques supporting industrial product design activity. The aims are to illustrate, practise and develop an appropriate level of practical knowledge and skill relating to the integrated activities of industrial product design and manufacture.

This module introduces the principles of real time computer systems and illustrates their practical implementation using a system based on an ARM Cortex-M3 microcontroller.

Various tools and techniques are necessary for the development of real-time and embedded systems. These will include system architecture, low-level assembly programming, high level languages, design and scheduling methodologies as well as verification.

Upon completing this module, students will be able to demonstrate the understanding of requirements placed on real-time systems; be able to select an appropriate architecture to meet a real-time requirement, select an appropriate operating system and program design, implement the design of a real-time system, and verify the e functionality of a real-time system.

The course aims to introduce various aspects of robotics and industrial automation with the use of robotic arms, sensors, actuators, and computers. Students will learn to describe positions and orientations in 3D space, derive direct and inverse kinematics, and calculate various physical quantities, e.

Students will relate these robotic theories to common applications in the industries, such as employing robotic manipulator for autonomous welding, and understand the working principles of various types of sensors, amplifiers, robotic arms, and industrial automation technologies.

This module provides design practice and engineering skills in terms of product development, design and test, component selection, evaluation, project planning, budgetting and documentation for the design of mechatronics systems. It integrates material taught in numerous modules, both electrical and mechanical.

This module is intended for students with some basic knowledge in electronics and circuits, as a follow-on course from Fundamentals of Electronics and Circuits.

Mechanical Engineering

Mechanical engineers design, build and analyze motor vehicles, aircraft, heating and cooling systems, watercraft, manufacturing plants, industrial equipment and machinery, robotics, medical devices, alternative energy and more. Mechanical engineering is an incredibly broad field, offering a variety of opportunities in the engineering, technology and other industries. For more information on average mechanical engineering salaries across the country, visit EngineerSalary. Applied Mechanics looks at shock and vibration, dynamics and motion, and fracture and failure in components. Fluids engineers design and build systems that control or utilize flow, such as pumps, turbines, compressors, valves, pipelines and fluid systems in vehicles.

Engineers are problem solvers, inventors and innovators! They find solutions to real-life problems by using science and technology. Engineers make up a large proportion of the professionals in the space sector, and for good reason: engineering is key to the success of space operations.

Programme Overview Mechanical Design Engineering is one of the oldest and broadest engineering disciplines. It integrates the understanding of core mechanicals and materials with the design process facilitated by the knowledge of manufacturing technologies and engineering principles. It involves the production and usage of mechanical power for the design and development of tools, machines or structures comprising moving parts that work together to make life easier. Mechanical Design Engineering makes the world go round, with applications for almost everything from taps to dams, bicycles to aircraft. This degree programme seeks to meet the industrial challenges and demands by producing innovative engineers with the capabilities and aptitude for the design of engineering products.

Careers in space – Engineers

If you have any trouble logging in to your account, contact us. To start 3D printing or Laser Cutting, you'll need to create an account here. Once done, you'll be able to upload your files and get live quotes of yours parts. Already have an account? Log In. Posted By Lucie Gaget on Nov 14, Are you in a mood for some history? Today, we are going to take a look at the history of mechanical engineering.

Mechanical engineering

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Mechanical engineering , the branch of engineering concerned with the design, manufacture, installation, and operation of engines and machines and with manufacturing processes. It is particularly concerned with forces and motion.

Growing demand for modern and complex industrial machinery, machine tools, robotics and computer-controlled processes require highly qualified technologists for their development, manufacture, use and support. Specialists in mechanical engineering are professionals who are concerned with the principles of force, energy and motion. The study programme provides deep understanding of fundamentals of Mechanics.

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The Department of Mechanical Engineering prepares students to meet the needs of regional petrochemical, aerospace, manufacturing and oil industries by employing emerging technologies in the classroom and in research settings. The Department of Mechanical Engineering offers a curriculum based on solid engineering foundations leading to the bachelor of science degree in mechanical engineering. The department has a goal of producing well-educated mechanical engineers, who will be successfully employed at the regional and national levels, or who will continue on with graduate studies. In support of the urban mission of the University, the undergraduate program has particular emphasis on serving non-traditional as well as traditional students.

Applicants must meet all entrance requirements and will be accepted on a first qualified basis as long as space remains. The Mechanical Engineering Technology diploma and the Mechanical Engineering degree share a common first year. Near the end of first year, students rank their preferences for the next year s of the program:. The number of positions in the degree and in each of the diploma options is limited. When demand exceeds capacity, entry is competitive and based on GPA in the first year of the program. See each program page for additional requirements.

Manufacturing engineering

Students will have a choice of specialisation in Design or Mechatronics. Under the Design specialisation, students will learn the concepts of digital manufacturing and design through modules in additive engineering, advanced materials technology, mechanical design and microelectronics for engineering products. Students in the Mechatronics specialisation will learn the special skill sets in IIoT used for automation and robotics, unmanned systems, co-bot design and build, as well as machine learning. Graduates from this programme will be equipped with sound principles in mechanical design or mechatronics as well as deep knowledge in digitalisation. They will be practice-oriented and innovative individuals with the right skill sets for the future digital economy. Subject to approval, diploma applicants may be granted module exemptions, based on the modules taken during their diploma. Academic Calendar.

R&D Mechanical Design Engineer; Development Engineer (Mechanical Design); Automation Engineer MEC Materials and Manufacturing Technology.

Mechanical engineering is the discipline that applies engineering physics , engineering mathematics , and materials science principles to design , analyze, manufacture, and maintain mechanical systems. It is one of the oldest and broadest of the engineering disciplines. The mechanical engineering field requires an understanding of core areas including mechanics , dynamics , thermodynamics , materials science , structural analysis , and electricity. In addition to these core principles, mechanical engineers use tools such as computer-aided design CAD , computer-aided manufacturing CAM , and product life cycle management to design and analyze manufacturing plants , industrial equipment and machinery , heating and cooling systems , transport systems, aircraft , watercraft , robotics , medical devices , weapons , and others.

The history of mechanical engineering

Manufacturing Engineering it is a branch of professional engineering that shares many common concepts and ideas with other fields of engineering such as mechanical, chemical, electrical, and industrial engineering. Manufacturing engineering requires the ability to plan the practices of manufacturing; to research and to develop tools, processes, machines and equipment; and to integrate the facilities and systems for producing quality products with the optimum expenditure of capital. Manufacturing Engineering is based on core industrial engineering and mechanical engineering skills, adding important elements from mechatronics, commerce, economics and business management. This field also deals with the integration of different facilities and systems for producing quality products with optimal expenditure by applying the principles of physics and the results of manufacturing systems studies, such as the following:.

Active on the engines, aircraft interiors and equipment markets, Safran offers a comprehensive range of solutions to civil and military airframers as well as airlines. For more than 50 years, Safran has been facilitating access to space, a strategic sector for State sovereignty. Through a wide range of products, Safran caters to the needs of air, land and sea armed forces in numerous countries worldwide. As a high-tech industrial Group operating on all continents, Safran is a key player in the propulsion and aerospace equipment, space and defense sectors.

Whether it's a dentist's drill or a tunnel drill, an automobile assembly line or a CD player, somewhere in the course of its development, a mechanical engineer has had a hand in its design. Mechanical engineers design, develop and build an enormous range of technical systems and mechanisms for industry and consumers.

В чем же проблема? - Джабба сделал глоток своей жгучей приправы. - Передо мной лежит отчет, из которого следует, что ТРАНСТЕКСТ бьется над каким-то файлом уже восемнадцать часов и до сих пор не вскрыл шифр. Джабба обильно полил приправой кусок пирога на тарелке. - Что-что. - Как это тебе нравится.

Он присел на край койки.  - Теперь, мистер Клушар, позвольте спросить, почему такой человек, как вы, оказался в таком месте. В Севилье есть больницы получше.

- Этот полицейский… - Клушар рассердился.  - Он уронил меня с мотоцикла, бросил на улице, залитого кровью, как зарезанную свинью. Я еле добрел .

Вгляделся в полоску на пальце и пристыжено покраснел.  - О Боже, - хмыкнул он, - значит, эта история подтверждается. Беккеру даже сделалось дурно.

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