전기공학

토목 공학 강좌는 자동차 설계, 항공학, 로봇 공학 및 제조 업체에 사용되는 것을 포함하여 기계 시스템을 설계하고 생성하는 기술을 발달시켜줍니다. 부주제로는 응용 역학, 유체 역학, 열전달 등을 다룹니다.

...

학위 취득

전기공학에서 가장 인기 있는 수료증

Design innovative solutions to the world’s most pressing environmental challenges.

Learn to drive innovation with an MSc in Innovation and Entrepreneurship.

가장 인기 있는 전기공학 강좌

최상급 전기공학 강좌

디지털 제조 및 CAD를 활용한 제조 방식 재구축

    전기공학에 대한 자주 묻는 질문

  • Mechanical engineers are responsible for the design, manufacture, and proper maintenance of machines and mechanical systems. A machine is defined by the Oxford Dictionary as “any device that transmits a force or directs its application,” but a less technical definition is that machines are simply anything that moves or has moving parts. When you consider just how much of our fast-moving world is dependent on these machines, broadly defined, it’s no wonder that this subfield of engineering has been critically important to society since the dawn of the Industrial Age.

    Technology has come a long way since the earliest steam engines, of course. Today, mechanical engineers are creating incredibly complex machines to do work across a growing and diverse range of fields, from perennially important industries such as automotive and manufacturing to emerging high-tech areas like aeronautics, biotechnology, and robotics. Mechanical engineering is also shrinking in scale, designing microelectromechanical and even nanoelectromechanical devices and systems that may be invisible to us but are increasingly important to the latest technologies.

    Regardless of the scale of the machines in question, the field of mechanical engineering requires core skills across several areas, including calculus, physics, fluid dynamics, thermodynamics, and more. This background, along with much more specialized knowledge in subject-specific areas, enables mechanical engineers to analyze the physical and environmental forces a machine will encounter during operation and then create designs to enable it to perform its function reliably.