Mechanical Engineer
What is this job like?
Mechanical engineering is one of the broadest engineering disciplines. Mechanical engineers research, design, develop, build, and test mechanical and thermal sensors and devices, including tools, engines, and machines.
Mechanical engineers generally work in offices. They may occasionally visit worksites where a problem or piece of equipment needs their personal attention. In most settings, they work with other engineers, engineering technicians, and other professionals as part of a team.
Mechanical engineers work mostly in engineering services, research and development, manufacturing industries, and the federal government.
How do you get ready?
Mechanical engineers typically need a bachelor’s degree in mechanical engineering or mechanical engineering technology. A graduate degree is typically needed for promotion into managerial positions.
Engineers should be creative, inquisitive, analytical, and detail-oriented. They should be able to work as part of a team and to communicate well, both orally and in writing. Communication abilities are becoming increasingly important as engineers interact more frequently with specialists in a wide range of fields outside engineering.
Mechanical engineers who sell services publicly must be licensed in all states and the District of Columbia.
How much does this job pay?
The median annual wage for mechanical engineers was $84,190 in May 2016.
How many jobs are there?
Mechanical engineers held about 277,500 jobs in 2014.
What about the future?
Employment of mechanical engineers is projected to grow 5 percent from 2014 to 2024, about as fast as the average for all occupations.
Job prospects may be best for those who keep up with the most recent advances in technology.
Some information on this page has been provided by the U.S Bureau of Labor Statistics.
Overview:
Mechanical engineering is one of the broadest engineering disciplines. Mechanical engineers research, design, develop, build, and test mechanical and thermal sensors and devices, including tools, engines, and machines.
Mechanical engineers typically do the following:
- Analyze problems to see how mechanical and thermal devices might help solve a particular problem
- Design or redesign mechanical and thermal devices or subsystems, using analysis and computer-aided design
- Develop and test prototypes of devices they design
- Analyze the test results and change the design or system as needed
- Oversee the manufacturing process for the device
Mechanical engineers design and oversee the manufacture of many products ranging from medical devices to new batteries.
Mechanical engineers design power-producing machines, such as electric generators, internal combustion engines, and steam and gas turbines, as well as power-using machines, such as refrigeration and air-conditioning systems.
Mechanical engineers design other machines inside buildings, such as elevators and escalators. They also design material-handling systems, such as conveyor systems and automated transfer stations.
Mechanical engineers use many types of tools, engines, and machines. Examples include the following:
- Power-producing machines such as electric generators, internal combustion engines, and steam and gas turbines
- Power-using machines, such as refrigeration and air-conditioning
- Industrial production equipment, including robots used in manufacturing
- Other machines inside buildings, such as elevators and escalators
- Machine tools and tools for other engineers
- Material-handling systems, such as conveyor systems and automated transfer stations
Like other engineers, mechanical engineers use computers extensively. Mechanical engineers are routinely responsible for the integration of sensors, controllers, and machinery. Computer technology helps mechanical engineers:
- Create and analyze designs
- Run simulations and test how a machine is likely to work
- Interact with connected systems
- Generate specifications for parts
- Monitor the quality of products
- Control manufacturing and production
Work Environment:
Mechanical engineers held about 277,500 jobs in 2014. They work mostly in machinery manufacturing industries, engineering services, computer and electronic product manufacturing, research and development in the physical, engineering, and life sciences, and aerospace product and parts manufacturing.
Mechanical engineers generally work in offices. They may occasionally visit worksites where a problem or piece of equipment needs their personal attention. In most settings, they work with other engineers, engineering technicians, and other professionals as part of a team.
Most mechanical engineers work full-time, and about 1 in 3 worked more than 40 hours a week in 2014.
Education and Training:
Mechanical engineers typically need a bachelor’s degree in mechanical engineering or mechanical engineering technology. Mechanical engineering programs usually include courses in mathematics and life and physical sciences, as well as engineering and design courses. Mechanical engineering technology programs focus less on theory and more on the practical application of engineering principles. They may emphasize internships and co-ops to prepare students for work in industry.
Some colleges and universities offer 5-year programs that allow students to obtain both a bachelor’s and a master’s degree. Some 5-year or even 6-year cooperative plans combine classroom study with practical work, enabling students to gain valuable experience and earn money to finance part of their education.
ABET (formerly the Accreditation Board for Engineering and Technology) accredits programs in engineering and engineering technology. Most employers prefer to hire students from an accredited program. A degree from an ABET-accredited program is usually necessary to become a licensed professional engineer.
Licensure is not required for entry-level positions as a mechanical engineer. A Professional Engineering (PE) license, which allows for higher levels of leadership and independence, can be acquired later in one’s career. Licensed engineers are called professional engineers (PEs). A PE can oversee the work of other engineers, sign off on projects, and provide services directly to the public. State licensure generally requires:
- A degree from an ABET-accredited engineering program
- A passing score on the Fundamentals of Engineering (FE) exam
- Relevant work experience, typically at least 4 years
- A passing score on the Professional Engineering (PE) exam
The initial FE exam can be taken after one earns a bachelor’s degree. Engineers who pass this exam are commonly called engineers in training (EITs) or engineer interns (EIs). After meeting work experience requirements, EITs and EIs can take the second exam, called the Principles and Practice of Engineering.
Several states require engineers to take continuing education to renew their licenses every year. Most states recognize licensure from other states, as long as the other state’s licensing requirements meet or exceed their own licensing requirements.
Several professional organizations offer a variety of certification programs for engineers to demonstrate competency in specific fields of mechanical engineering.
A Ph.D. is essential for engineering faculty positions in higher education, as well as for some research and development programs. Mechanical engineers may earn graduate degrees in engineering or business administration to learn new technology, broaden their education, and enhance their project management skills. Mechanical engineers may become administrators or managers after obtaining the requisite experience.
Skills to Develop:
Creativity: Mechanical engineers design and build complex pieces of equipment and machinery. A creative mind is essential for this kind of work.
Listening skills: Mechanical engineers often work on projects with others, such as architects and computer scientists. They must listen to and analyze different approaches made by other experts to complete the task at hand.
Math skills: Mechanical engineers use the principles of calculus, statistics, and other advanced subjects in math for analysis, design, and troubleshooting in their work.
Mechanical skills: Mechanical skills allow engineers to apply basic engineering concepts and mechanical processes to the design of new devices and systems.
Problem-solving skills: Mechanical engineers need good problem-solving skills to take scientific discoveries and use them to design and build useful products.
Job Outlook:
Employment of mechanical engineers is projected to grow 5 percent from 2014 to 2024, about as fast as the average for all occupations. Mechanical engineers can work in many industries and on many types of projects. As a result, their growth rate will differ by the industries that employ them. Job prospects may be best for those who stay informed regarding the most recent advances in technology.
Mechanical engineers are projected to experience much faster than growth in engineering services as companies continue to contract work from these firms. Mechanical engineers will also remain involved in various manufacturing industries, particularly transportation equipment. They will be needed to design the next generations of vehicles and vehicle systems, such as hybrid-electric cars and clean diesel automobiles.
Mechanical engineers often work on the newest industrial pursuits. The fields of alternative energies, remanufacturing, and nanotechnology may offer new opportunities for occupational growth. Remanufacturing—rebuilding goods for a new use after they have worn out or become nonfunctional—holds promise because it reduces the cost of waste disposal.
Nanotechnology, which involves manipulating matter at the tiniest levels, may affect the employment of mechanical engineers because they will be needed to design production projects on the basis of that technology. Nanotechnology will be useful in areas such as healthcare and designing more powerful computer chips.
Earnings:
The median annual wage for mechanical engineers was $84,190 in May 2016. The median wage is the wage at which half the workers in an occupation earned more than that amount and half earned less. The lowest 10 percent earned less than $54,420, and the highest 10 percent earned more than $131,350.
Mechanical Engineering - Sloan Career Cornerstone Center
Mechanical Engineering - Wikipedia overview
NASA Career Information - NASA student career site
Earth Science Careers - NASA site for related careers
Discover Engineering - Answers question: What is engineering?
Engineer Girls - National Academy of Engineering site for girls
eGFI (Engineering, Go For It) - ASEE site for K-12 STEM & Engineering
Women of NASA - Profiles of women at NASA
Look to the Future: Careers in Space - NASA careers site
American Society of Mechanical Engineers - ASME student resource page
Mechanical Engineers - Bureau of Labor Statistics outlook