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There are over 7000 skyscrapers every year and thousands of dangerous tasks are done by robots. These are just an example of what Mechanical Engineering can present to society. Mechanical engineering is a vast and dynamic field that touches almost every aspect of our daily lives. From the cars we drive to the heating systems that keep us warm, mechanical engineers play a very important role in shaping our world.
Mechanical Engineering is a domain of Engineering that focuses particularly on motion and force. It is one of the oldest branches of Engineering that combines between engineering physics, design, principles of mathematics, and material science.
In this guide we provide students with all needed information about the various fields of Mechanical Engineering that students can apply for no matter what study level they are aspiring for. After reading this, you can reach out to our Edmov experts and get tailored help in decision making and application process as well. Let us dive in.
Automotive engineering is a part of the larger automotive industry. Engineers in this field are tasked with creating vehicles that meet standards and function effectively. This area of engineering necessitates extensive research and a top-notch education to develop cutting-edge equipment. To pursue a career as an Automotive Engineer, completion of a four-year Bachelor’s degree is required. However, as not all colleges offer a specialized bachelor’s degree in automotive engineering, students aspiring to work in this field often choose to major in mechanical engineering.
Aerospace Engineering, often referred to by students as "rocket science," is an engineering branch that focuses on the design, development, testing, and production of aircraft, spacecraft, and related systems that travel through fluids. It is considered one of the best mechanical engineering field for the future.
This field combines mechanical and physical principles from aeronautics, propulsion, avionics, materials science, structural analysis, and manufacturing.
Aerospace Engineering can be studied at various levels, including advanced diploma, bachelor's, master's, and Ph.D., in aerospace engineering departments at many universities, and sometimes in mechanical engineering departments.
Some universities offer specialized degrees in astronautical engineering, while others distinguish between aeronautical and astronautical engineering. Graduate degrees are available in advanced or specialized areas relevant to the aerospace industry.
Manufacturing Engineering, often called production Engineering, shares core concepts with Mechanical Engineering. Manufacturing Engineers are responsible for a product from the moment of design through development and until it reaches the point of being a functional product.
Manufacturing engineers possess advanced skills in mathematics and science, are organized and analytical thinkers, and thrive in team settings. As a manufacturing engineer, your responsibilities encompass designing, developing, and testing the processes involved in product manufacturing.
Mechanical Engineering is the best career for those who aim at working in a challenging environment that mixes between individual and team work.
Robotics Engineers make work on designing and creating robots that can do both human and non-human jobs and aid humans in the performance of difficult tasks. Robotics Engineers create robots that have different applications in various fields such as medicine, defense and aerospace.
The study of Robotics Engineering is considered one of the best mechanical engineering fields for the future. It includes topics such as robotics fundamentals, kinematics and dynamics, control systems, sensor integration, computer vision, artificial intelligence, machine learning, mechatronics, industrial automation, and robotic programming.
The Biomechanical Engineering major offers a foundational understanding of mechanics as applied to biology and medicine. It is ideal for those considering future graduate studies in bioengineering, medicine, or related fields.
The main duties of a Biomedical Engineer Include designing equipment. The kind of equipment varies from artificial body parts to machines that can be used in disease detection.
This program aims at preparing students and training them to apply mathematical, scientific, and engineering principles, along with technical skills, to manipulate matter at the atomic and molecular levels.
The study of Nanotechnology focuses on designing, fabricating, and integrating nanoscale structures, devices, and systems. The curriculum includes courses in materials science, thermodynamics, nanomaterials, nanoelectronics, and the fabrication and testing of nano/micro devices.
The best universities around the world include the study of Mechatronics within their scope of Engineering Bachelor Degrees.
Mechatronics Engineers are required to provide innovative and sustainable solutions to challenges in industry.
Mechatronics Engineering integrates practical skills from mechanical engineering, electrical engineering, and computer science. Graduates are highly skilled in the hands-on application of robotic technology and have a wide range of industries to choose from for their careers.
Thermal engineering encompasses technologies that generate heat energy, transfer heat between components, or manage heat transfer to or from specific components.
This field is essential for applications such as climate control, HVAC systems, air quality management, and much more .
As a subfield of mechanical engineering, thermal engineering often appeals to individuals interested in hands-on work with engineering equipment.
Combustion engineering includes utilizing the energy from fuel heating. Its applications range from home heating systems to automotive engines and include different manufacturing processes.
Professionals in combustion engineering typically hold degrees in mechanical engineering or chemical engineering.
Combustion engineering focuses on applying the science behind combustion to industrial settings. Combustion engineers oversee the planning, implementation, testing, and design of combustion equipment and new energy-burning systems.
The Graduate Specialization in Automotive Systems offers students in the mechanical engineering program a distinctive chance to gain specialized training, unique skills, and practical experience in their field of interest.
This specialization enriches their degree by focusing on automotive systems and smart mobility.
Curriculums in this specialization are designed to strengthen the skills and knowledge that graduate engineers will utilize to tackle intricate automotive challenges in their careers.
This sub-branch of Mechanical Engineering covers a wide range of advanced subjects involving thermodynamics, heat transfer, fluid mechanics, and chemical and phase change processes in engineered systems.
Within this division, students, faculty, and research staff make use of advanced experimental diagnostics and numerical simulation tools to help them tackle challenged related to energy storage, conversion, and utilization; environmental sustainability and safety; sustainable transportation and fuels; water purification and treatment; and thermochemical and material processing applications.
Mechanical design, usually referred to as machine design or sometimes engineering design, includes the process of creating efficient parts or components for machinery.
Engineers in this field analyze how mechanical elements function under different conditions to ensure the creation of reliable systems. The primary objective of mechanical design is to develop machinery designs that are both safe and complies with client needs.
The study in this field focuses on principles and methodologies for designing and regulating both engineered and natural systems.
This specialization encourages engineers to be innovative when it comes to applications involving systems composed of multiple interacting energetic devices .
Key areas of focus include acoustics, applied mechanics, bioengineering, computational sciences, material behavior and design, electromechanics, control theory, multibody dynamics, and system dynamics.
Transportation engineering applies principles from science, technology, engineering, and mathematics to tackle the complexities of planning, designing, constructing, maintaining, and operating transportation infrastructure systems.
Transportation planning involves analyzing and modeling travel behavior to predict trips, evaluate the need for new infrastructure, and recommend investment strategies and policies to manage future traffic problems and other challenges.
Choosing the best mechanical engineering specialization is challenging. The process involves assessing how each field applies fundamental mechanical engineering concepts to address real-world challenges.
For example , automotive engineers focus on thermodynamics to enhance engine efficiency, ensuring optimal performance and fuel economy.
Aerospace engineers, on the other hand, aim at applying the principles of fluid mechanics and structural analysis to design aircraft and spacecraft that are both safe and aerodynamically efficient.
Moreover, Biomechanical engineers employ the mechanical principles they study to come up with innovative medical devices and prosthetics, to improve mobility and healthcare outcomes.
In renewable energy, engineers utilize thermodynamics and fluid dynamics to optimize systems like wind turbines and solar panels for maximum energy production.
Mechanical engineers are an integral part of multiple industries, from aerospace and automotive to healthcare, renewable energy, manufacturing, and construction, contributing to technological advancements and the overall progress of societies through their specialized skills and innovations.