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Career and Education Opportunities for Biomedical Engineers in Raleigh, North Carolina

For those living in the Raleigh, North Carolina area, there are many career and education opportunities for biomedical engineers. There are currently 570 jobs for biomedical engineers in North Carolina and this is projected to grow by 38% to 790 jobs by 2016. This is not quite as good as the nation as a whole, where employment opportunities for biomedical engineers are expected to grow by about 72.0%. Biomedical engineers generally 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.

A person working as a biomedical engineer can expect to earn about $33 per hour or $70,710 per year on average in North Carolina and about $37 hourly or $77,400 yearly on average in the U.S. as a whole. Biomedical engineers earn less than people working in the category of Engineering generally in North Carolina and less than people in the Engineering category nationally. People working as biomedical engineers can fill a number of jobs, such as: biomedical equipment technician , clinical engineer, and biomedical engineering supervisor.

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

CAREER DESCRIPTION: Biomedical Engineer

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

In general, biomedical engineers 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.

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

It is important for biomedical engineers to advise hospital administrators on the planning and use of medical equipment. They are often called upon to set up and/or repair biomedical equipment. They also advise and help in the application of instrumentation in clinical environments. They are sometimes expected to layout and deliver technology to help people with disabilities. Somewhat less frequently, biomedical engineers are also expected to teach biomedical engineering or disseminate knowledge about field through writing or consulting.

Biomedical engineers sometimes are asked to layout and develop medical diagnostic and clinical instrumentation, equipment, and procedures, using the principles of engineering and biobehavioral sciences. They also have to be able to design models or computer simulations of human biobehavioral systems to obtain data for measuring or controlling life processes and research new materials to be used for products. And finally, they sometimes have to conduct research, along with life scientists and medical scientists, on the engineering aspects of the biological systems of humans and animals.

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

Similar jobs with educational opportunities in Raleigh include:

  • Aerodynamics Engineer. Perform a variety of engineering work in designing, constructing, and testing aircraft, missiles, and spacecraft. May conduct basic and applied research to evaluate adaptability of materials and equipment to aircraft design and manufacture. May recommend improvements in testing equipment and techniques.
  • 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.
  • 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.
  • 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: Biomedical Engineer Training

University of North Carolina at Chapel Hill - Chapel Hill, NC

University of North Carolina at Chapel Hill, 103 South Bldg Cb 9100, Chapel Hill, NC 27599. University of North Carolina at Chapel Hill is a large university located in Chapel Hill, North Carolina. It is a public school with primarily 4-year or above programs. It has 28,567 students and an admission rate of 35%. University of North Carolina at Chapel Hill has a master's degree and a doctor's degree program in Biomedical/Medical Engineering which graduated four and nine students respectively in 2008.

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 Biomedical/Medical Engineering which graduated four, seven, and zero students respectively in 2008.

Duke University - Durham, NC

Duke University, 103 Allen Bldg, Durham, NC 27708. Duke University is a large university located in Durham, North Carolina. It is a private not-for-profit school with primarily 4-year or above programs. It has 13,871 students and an admission rate of 23%. Duke University has bachelor's degree, master's degree, and doctor's degree programs in Biomedical/Medical Engineering which graduated ten, twenty-two, and twenty-five students respectively in 2008.

CERTIFICATIONS

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.

Certified Water Technologist: The Certified Water Technologist (CWT) program represents the highest professional credential in the industrial and commercial water treatment field.

For more information, see the Association of Water Technologies website.

LOCATION INFORMATION: Raleigh, North Carolina

Raleigh, North Carolina
Raleigh, North Carolina photo by Jmturner

Raleigh is located in Wake County, North Carolina. It has a population of over 392,552, which has grown by 42.2% over the last ten years. The cost of living index in Raleigh, 88, is well below the national average. New single-family homes in Raleigh are valued at $217,600 on average, which is far greater than the state average. In 2008, 1,685 new homes were built in Raleigh, down from 3,224 the previous year.

The top three industries for women in Raleigh are educational services, health care, and accommodation and food services. For men, it is construction, professional, scientific, and technical services, and accommodation and food services. The average commute to work is about 22 minutes. More than 44.9% of Raleigh residents have a bachelor's degree, which is higher than the state average. The percentage of residents with a graduate degree, 14.4%, is higher than the state average.

The unemployment rate in Raleigh is 7.2%, which is less than North Carolina's average of 10.6%.

The percentage of Raleigh residents that are affiliated with a religious congregation, 43.8%, is less than both the national and state average. Highland Church, Hillcrest Church and Wake Chapel are all churches located in Raleigh. The most prominent religious groups are the Southern Baptist Convention, the Catholic Church and the United Methodist Church.

Raleigh is home to the North Ridge Country Club and the Pamlico Junction as well as Carl Alwin Schenck Memorial Forest and Rothgeb Park. Visitors to Raleigh can choose from Hampton Inn - Capital Blvd. North, Best Western Raleigh Inn and Diamond Hospitality Inc for temporary stays in the area.