IIPM SCHOOL OF ENGINEERING AND TECHNOLOGY started undergraduate course in Mechanical Engineering with intake capacity of 60 nos.of seats in 2017.
Mechanical Engineering is the most diverse and versatile trade of the engineering disciplines. Apart from physics and mathematics, it encompasses key components of production, thermal, design, automobile and even materials science. Mechanical engineering touches virtually every aspect of modern life, from mobile phones and biomedical devices, to aircrafts and power plants. Mechanical engineers also deals with the economic behaviour of almost every components starting from raw material to final product of an industry.
Mechanical engineers evaluate their work by using the principles of motion, energy, and force-ensuring that designs function safely, efficiently, and reliably, all at an optimal cost.
Besides this, mechanical engineers can also be found in sales, engineering maintenance, and corporate relation. Versatility and precision are another unique advantages in a world that is undergoing constant economic, political, industrial, and social change. Mechanical engineers are educated and positioned, not only to adapt, but to define and direct change.
The Department offers many options extending across many interdisciplinary specialties. Our Department is concerned with all types of machinery in industries and their mechanism and functioning; the design, development, construction, production, installation, operation and maintenance; such as large steam and gas turbines, components of thermal power stations, internal combustion engines, jet engines, machine tools, air conditioning and heating machines, refrigerators etc. Our Department prepares the mechanical engineers who are the driving force behind many of our technologies and industrial processes.
HERE ARE THE KEY ASPECTS OF MECHANICAL ENGINEERING
In static, study focuses on how forces are transmitted to and throughout a structure which is fixed one. Once a system is in motion, mechanical engineers look at dynamic or what velocities, accelerations and resultant forces come into force. Kinematics then determine how a mechanism behaves as it moves through its frame of motion.
Material science deals to determine the best materials for different applications. A part of that is strength of material—testing support loads, ductility, brittleness, hardness malleability and other properties—which is essential for many construction, automobile, and design of components.
How different form of energy gets converted into useful work is the heart of thermodynamics, as well as determining what amount of energy is lost in the process. One specific kind of energy, heat transfer, is crucial in many applications and determining what are the modes of transferring heat from one place to another.
Fluid mechanics, which also has a variety of applications, looks at many properties including pressure drops from fluid flow and working of hydraulic machinery.
Manufacturing is the second step in mechanical engineering after design. Within the field, researchers investigate the best processes to make manufacturing more efficient. Laboratory methods focus on improving how to measure both thermal and mechanical engineering products and processes.
All the equipment produces vibrations, another field of mechanical engineering, in which researchers focuses on how to predict and control vibrations.
Engineering economics makes mechanical designs relevant and usable in the real world by estimating manufacturing and life cycle costs of materials, designs, and other engineered products.