Popular Careers

Career Development

Career development resources for aspiring professionals.

Career Change Center

Career change guides, tutorials and resources for professionals in transition.

Job Search Resources

Job search resources, websites, guides and directories for job seekers.


Career and Education Opportunities for Aerodynamics Engineers in Durham, North Carolina

Aerodynamics engineers can find both educational opportunities and jobs in the Durham, North Carolina area. About 500 people are currently employed as aerodynamics engineers in North Carolina. By 2016, this is expected to grow by 28% to 640 people employed. This is better than the national trend for aerodynamics engineers, which sees this job pool growing by about 10.4% over the next eight years. Aerodynamics engineers generally perform a variety of engineering work in designing, constructing, and testing aircraft, missiles, and spacecraft.

A person working as an aerodynamics engineer can expect to earn about $38 per hour or $80,650 yearly on average in North Carolina and about $44 per hour or $92,520 annually on average in the U.S. as a whole. Compared with people working in the overall category of Engineering, people working as aerodynamics engineers in North Carolina earn more. They earn more than people working in the overall category of Engineering nationally. Jobs in this field include: propeller engineer, airframe design engineer, and rocket scientist.

There are twenty-six schools of higher education in the Durham area, including one within twenty-five miles of Durham where you can get a degree to start your career as an aerodynamics engineer. The most common level of education for aerodynamics engineers is a Bachelor's degree. It will take about four years to learn to be an aerodynamics engineer if you already have a high school diploma.

CAREER DESCRIPTION: Aerodynamics Engineer

Aerodynamics Engineer video from the State of New Jersey Dept. of Labor and Workforce Development

In general, aerodynamics engineers perform a variety of engineering work in designing, constructing, and testing aircraft, missiles, and spacecraft. They also may conduct basic and applied research to evaluate adaptability of materials and equipment to aircraft design and manufacture.

Every day, aerodynamics engineers are expected to be able to read and understand documents and reports. They need to think through problems and come up with general rules. It is also important that they listen to and understand others in meetings.

It is important for aerodynamics engineers to direct and schedule efforts of engineering or technical personnel designing or testing of aircraft or aerospace products. They are often called upon to formulate conceptual layout of aeronautical or aerospace products or systems to fit customer requirements. They also analyze project requests and proposals and engineering data to establish feasibility and production time of aerospace or aeronautical product. They are sometimes expected to inspect performance reports and documentation from customers and field engineers, and inspect malfunctioning or damaged products to establish problem. Somewhat less frequently, aerodynamics engineers are also expected to evaluate and approve selection of vendors by study of past performance and new advertisements.

Aerodynamics engineers sometimes are asked to direct research and development programs. and formulate and direct efforts concerned with investigating and resolving customers' reports of technical problems with aircraft or aerospace vehicles. And finally, they sometimes have to evaluate and approve selection of vendors by study of past performance and new advertisements.

Like many other jobs, aerodynamics engineers must be thorough and dependable and be reliable.

Similar jobs with educational opportunities in Durham include:

  • Agricultural Engineer. Apply knowledge of engineering technology and biological science to agricultural problems concerned with power and machinery, electrification, structures, soil and water conservation, and processing of agricultural products.
  • Biomedical Engineer. Apply knowledge of engineering, biology, and biomechanical principles to the design, development, and evaluation of biological and health systems and products, such as artificial organs, prostheses, instrumentation, medical information systems, and health management and care delivery systems.
  • Chemical Engineer. Design chemical plant equipment and devise processes for manufacturing chemicals and products, such as gasoline, synthetic rubber, and pulp, by applying principles and technology of chemistry, physics, and engineering.
  • Civil Engineer. Perform engineering duties in planning, designing, and overseeing construction and maintenance of building structures, and facilities, such as roads, railroads, airports, bridges, harbors, channels, dams, irrigation projects, pipelines, power plants, water and sewage systems, and waste disposal units. Includes architectural, structural, and geo-technical engineers.
  • Computer Engineer. Research, design, and test computer or computer-related equipment for commercial, industrial, or scientific use. May supervise the manufacturing and installation of computer or computer-related equipment and components.
  • Electrical Engineer. Design, develop, or supervise the manufacturing and installation of electrical equipment, components, or systems for commercial, industrial, or scientific use.
  • Electronics Engineer. Research, design, and test electronic components and systems for commercial, industrial, or scientific use utilizing knowledge of electronic theory and materials properties. Design electronic circuits and components for use in fields such as telecommunications, aerospace guidance and propulsion control, acoustics, or instruments and controls.
  • Fire Prevention Research Engineer. Research causes of fires, determine fire protection methods, and design or recommend materials or equipment such as structural components or fire-detection equipment to assist organizations in safeguarding life and property against fire, explosion, and related hazards.
  • Health, Safety, and Environment Manager. Plan, implement, and coordinate safety programs, requiring application of engineering principles and technology, to prevent or correct unsafe environmental working conditions.
  • Industrial Engineer. Design, develop, and evaluate integrated systems for managing industrial production processes including human work factors, quality control, inventory control, logistics and material flow, cost analysis, and production coordination.
  • Industrial Engineering Technician. Apply engineering theory and principles to problems of industrial layout or manufacturing production, usually under the direction of engineering staff. May study and record time, motion, and speed involved in performance of production, maintenance, and other worker operations for such purposes as establishing standard production rates or improving efficiency.
  • Manufacturing Engineer. Apply knowledge of materials and engineering theory and methods to design, integrate, and improve manufacturing systems or related processes. May work with commercial or industrial designers to refine product designs to increase producibility and decrease costs.
  • Materials Engineer. Evaluate materials and develop machinery and processes to manufacture materials for use in products that must meet specialized design and performance specifications. Develop new uses for known materials. Includes those working with composite materials or specializing in one type of material, such as graphite, metal and metal alloys, ceramics and glass, plastics and polymers, and naturally occurring materials.
  • Mechanical Engineer. Perform engineering duties in planning and designing tools, engines, and other mechanically functioning equipment. Oversee installation, operation, and repair of such equipment as centralized heat, gas, and steam systems.
  • Nuclear Engineer. Conduct research on nuclear engineering problems or apply principles and theory of nuclear science to problems concerned with release, control, and utilization of nuclear energy and nuclear waste disposal.
  • Product Safety Engineer. Develop and conduct tests to evaluate product safety levels and recommend measures to reduce or eliminate hazards.

EDUCATIONAL OPPORTUNITIES: Aerodynamics Engineer Training

North Carolina State University at Raleigh - Raleigh, NC

North Carolina State University at Raleigh, 2101 Hillsborough Street, Raleigh, NC 27695-7001. North Carolina State University at Raleigh is a large university located in Raleigh, North Carolina. It is a public school with primarily 4-year or above programs. It has 32,871 students and an admission rate of 60%. North Carolina State University at Raleigh has bachelor's degree, master's degree, and doctor's degree programs in Aerospace, Aeronautical and Astronautical Engineering which graduated forty, eight, and four students respectively in 2008.

CERTIFICATIONS

Planning and Scheduling Professional: The PSP certification is to recognize specialists who meet a demanding set of planning and scheduling criteria by a rigorous examination, experience, education and ethical qualificaion.

For more information, see the AACE International (Association for the Advancement of Cost Engineering through total cost management) website.

Geometric Dimensioning & Tolerancing Professional - Technologist: ASME GDTP Certification provides the means to recognize proficiency in the understanding and application of the geometric dimensioning and tolerancing (GD&T) principles expressed in the ASME Y14.

For more information, see the American Society of Mechanical Engineers International website.

LOCATION INFORMATION: Durham, North Carolina

Durham, North Carolina
Durham, North Carolina photo by Specious

Durham is situated in Durham County, North Carolina. It has a population of over 223,284, which has grown by 19.4% over the last ten years. The cost of living index in Durham, 86, is well below the national average. New single-family homes in Durham are valued at $187,200 on average, which is well above the state average. In 2008, 1,082 new homes were built in Durham, down from 1,574 the previous year.

The three most popular industries for women in Durham are health care, educational services, and professional, scientific, and technical services. For men, it is construction, educational services, and health care. The average commute to work is about 21 minutes. More than 41.8% of Durham residents have a bachelor's degree, which is higher than the state average. The percentage of residents with a graduate degree, 18.3%, is higher than the state average.

The unemployment rate in Durham is 7.3%, which is less than North Carolina's average of 10.6%.

The percentage of Durham residents that are affiliated with a religious congregation, 39.3%, is less than both the national and state average. Laymans Church, Holy Infant Church and Homestead Heights Church are among the churches located in Durham. The most prominent religious groups are the Southern Baptist Convention, the United Methodist Church and the Catholic Church.

Durham is home to the Hope Valley Country Club and the Union Building as well as Durham County Stadium and Northgate Park. Shopping centers in the area include South Square Mall, Lakewood Shopping Center and Kings Plaza Shopping Center. Visitors to Durham can choose from Brownestone Inn, Durham-Days Inn ) and Hilton Durham for temporary stays in the area.