About Mechanical & Smart Manufacturing

As a branch of engineering, mechanical engineering combines engineering physics, mathematics, and materials science to design, analyse, manufacture, and maintain mechanical systems. It is one of the oldest and most diverse branches of engineering. The discipline of engineering that deals with the design, production, and operation of machinery. For mechanical engineers, it is essential to have a solid foundation in mechanics, dynamics, thermodynamics, materials science, structural analysis, and electricity. Additionally, mechanical engineers use computer-aided design (CAD), computer-assisted manufacturing (CAM), and product lifecycle management to design and analyse manufacturing plants, industrial equipment, heating and cooling systems, transport systems, aircraft, watercraft, robotics, medical devices, and weapons. During the Industrial Revolution in Europe in the 18th century, mechanical engineering emerged; however, its origins can be traced back several thousand years. In the 19th century, advances in physics led to the development of mechanical engineering science. Having evolved into a field incorporating new products, mechanical engineers today pursue actions in composites, mechatronics, and nanotechnology. Other engineering disciplines share the same foundation as structural engineering, including aerospace engineering, metallurgical engineering, civil engineering, electrical engineering, manufacturing engineering, chemical engineering, and industrial engineering. In addition to mechanical engineering, engineers may also work in areas of biomedical engineering, such as biomechanics, transport phenomena, bio mechatronics, bio nanotechnology, and modelling of biological systems.

What is Mechanical & Smart Manufacturing?

Mechanical engineers are responsible for taking a product from an idea to the market. To accomplish this, an engineer must understand the forces and thermal environment that a product, its parts, or its subsystems will encounter; design them for functionality, aesthetics, and durability; and determine the best manufacturing method so that the product operates without failure. Because of the breadth of the mechanical engineering discipline, students can choose careers that are not listed above. Regardless of the career path they envision themselves taking, a mechanical engineering education equips students with the skills to design an exceptional product or system; analytical tools to achieve their design goals; the ability to overcome any constraints; and the teamwork necessary to develop, market, and manufacture a product. Skills like these can be applied to launch careers in many other fields, including medicine, law, consulting, management, banking, and finance.

Eligibility and Career in Mechanical & Smart Manufacturing 

Biotechnology, materials science, and nanotechnology are expected to provide mechanical engineers with new career opportunities. Mechanical engineers specialising in design mechanics are increasingly interested in biotechnology, mainly because it can be applied to medical applications. The development of prosthetic devices and artificial organs is included in this area. To design and develop products that will withstand stress and be compatible with the human body, engineers collaborate with medical doctors. Students with a solid scientific, mathematical, and communication background can study mechanical engineering. Students interested in engineering should take algebra, geometry, trigonometry, and calculus courses in high school. Additional methods in chemistry, biology, and physics should be accepted as well.