Associate Degree in Aerospace Engineering

 

Associate Degree in Aerospace Engineering

There are small number of schools that offer associate degrees in aerospace engineering, but they usually reserve those degrees for engineers who have degrees in related fields, such as mechanical, electrical or computer engineering. Generally, the aerospace industry prefers job seekers with four-year Bachelor of Science degrees.

There are only a handful of universities accredited by the Accreditation Board for Engineering and Technology in the United States that offer aerospace engineering degrees. Aerospace engineers take two years of calculus, differential equations, physics and chemistry and two years of engineering coursework. Aerospace engineering students can expect to see the following engineering courses in their university's curriculum:

• Statics
• Dynamics of aerospace systems
• Control of aerospace systems
• Aerodynamics
• Thermodynamics
• Flight software systems
• Aerospace instrumentation and experimentation
• Aerospace structures
• Aircraft flight dynamics
• Space flight dynamics

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Acoustic Engineering Success Story

 

 Acoustic Engineering Success Story

The Bose company is a prime example of a firm that relies heavily on the expertise of sound engineers. Founded by Amar G. Bose, an engineer himself, who studied at the Massachusetts Institute of Technology (MIT), the firm built its reputation on developing and marketing audio equipment and systems of impeccable quality. The company’s products are popular among consumers, automobile manufactures and performing arts venues. The equipment developed by their sound engineers strives to simulate the quality experienced at a live concert hall. Bose has chosen to engage in long-term, higher-risk projects requiring immense research and development instead of providing cheaper products to its customers. This approach has paid off with the creation of noise-canceling audio equipment such as headphones as well as ingenious suspension systems for the automobile industry.

As a teacher at MIT for nearly 50 years, Bose instructed a course on acoustics that transcended mere technical matters into larger life lessons. Bose stressed to his students the importance of personal responsibility and having high standards for work and integrity. Many students attributed to Dr. Bose their resolve to take on more risky endeavors as well as the technical and critical-thinking skills to achieve success in their careers. The life of Bose and the success of his company serves as a model for all practitioners in the field, underscoring the importance of developing a well-rounded education and approach to successfully tackling both technical and more abstract challenges that they may encounter both in their personal and professional arenas.

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Agricultural Engineering Degree Career Outlook

Agricultural engineering degrees prepare students to work professionally in the many fields of agriculture. Subsets of the studies belonging to the classification of agriculture offer unlimited opportunities for involvement in this field. Demand for Agricultural Engineers has grown over the last 10 years.

Degrees in agricultural engineering cover all aspects of the industry, from water and waste issues, massive farming of foods and livestock, water farming, farming equipment, and farm economics to genetically designed corn and cows. Earning a degree gives students textbook knowledge and hands-on vision of their chosen field. Fieldwork and laboratory projects combined with actual practice provide a well-rounded education.

The bachelor of science is the first degree to obtain. While majoring in agricultural engineering, a student can minor is any other field. Often students will minor in a related subject such as economics, to enhance their food engineering major, for example.

Graduate students are eligible to pursue a number of advanced degrees, including the Master of Science, Master of Engineering, Master of Agriculture, Doctor of Philosophy and Doctor of Engineering. These students can major in bioacoustics, biomaterials science, bioprocess engineering, environmental and natural resource engineering, food engineering; food, feed and fiber processing; machine and energy systems; and systems analysis.

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Structural Engineering Education

Structural Engineering Education

Structural Engineering focuses on the support integrity of large developments such as buildings, bridges and stadiums. Structural engineers are responsible for some of the most import constructions in history, including Washington Roebling who built the Brooklyn Bridge in New York and Gustave Eiffel who completed The Eiffel Tower in Paris, France. Structural engineers traditionally collaborate with a team of professionals including architects, urban planners and civil engineers, among others, to realize the completion of a project.

Federal and local governments as well as private enterprises contract these practitioners for work throughout the world, whereby they are entrusted to ensure public safety by meeting building codes and standards. For buildings, these professionals achieve this by developing the components such as roof framing columns and foundations. In bridges, they develop the piers, deck and/or stringers. In addition, they select the most appropriate materials including wood, concrete, steel and/or aluminum, thereby protecting the structure and surrounding communities in the case of natural disasters, weather, collisions or explosions. To determine the best materials, structural engineers rely on digital hardware and software applications for modeling and analysis.

Employers require structural engineers to have a college degree in the discipline or comparable areas such as civil engineering. Most professionals have acquired a Master’s Degree or even a Ph.D. to distinguish themselves in the marketplace. Undergraduate students complete coursework in materials, algorithms, design and mechanics, among other concepts. Advanced academic training in the field facilitates a candidate’s ability to receive management positions in the industry as well as university teaching roles. At the Master’s Degree level, students complete classwork in advanced materials design principles, structural mechanics and seismology. For Ph.D. students, coursework includes classes in computer modeling, advanced renovation and restoration as well as risk analysis.

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Real Life Work Nature of Thermal Engineers

 

Real Life Work Nature of Thermal Engineers

Thermal engineers have been instrumental in changing the way people find and use energy throughout the world as well as in pushing space exploration into new realms. Most people think of Google as an Internet search engine company, but the firm has expanded its resources into creating better energy solutions for the planet. The firm actively recruits thermal engineers to work on its project for developing clean and affordable power grids. Their Energy Access team endeavors to recruit and nurture engineers to its efforts, underscoring its conviction in its identity as an engineering firm.

Moreover, the University College London (UCL) Mullard Space Science Laboratory considers the work of its thermal engineers as vital for enhancing space exploration initiatives. One of their professionals, Christine Brockley-Blatt, has exemplified the seamless transition these practitioners make from the classroom to real world applications. After completing her undergraduate degree in Mechanical Engineering and Physics, Brockley-Blatt completed an internship with an aerospace firm, whereby she trained on a project dealing with the landing gear and propeller technology for a medley of aircraft models. She then applied more of her thermal engineering training to an automotive firm. With UCL she currently works as a project manager on cooling technology in outer space exploration solutions. On a daily basis, she employs calculations in mechanical and thermal capacities, performs project management duties, and demonstrates oral and written communications. Her rich educational background and professional experience illuminate the depth and versatility the field requires of its practitioners to excel.

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Thermal Engineering Career Outlook

Professionals in the field of thermal engineering strive to develop more efficient means for transferring energy into more practical means, drawing on their expertise in heat transfer. Within an industrial context, these engineers work on solutions for fuels, exploring forms of chemical, electrical and mechanical energy. These professionals find specialization in the fields of high technology, solar power, oil and gas, power companies, as well as temperature control systems. Transforming power grids to create more affordable electricity has become one of the most popular fields utilizing the expertise of thermal engineers.

If you want to know more about becoming a thermal engineer, contact the schools listed here to learn more. It’s important to talk to as many schools as you can to determine the best way forward.

Thermal engineers dedicate their efforts to refining electronics systems and safety applications. They collaborate extensively with groups of hardware and software experts at all stages of the product cycle from initial design through the manufacturing and installation of products and systems. In this capacity, they may develop models for industrial assets rooted in computer projects for optimizing source materials and functionality.

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Mining and Geological Engineering

Mining and geological engineering focuses primarily on the study and design of creating safe and effective means to extract metals and minerals for industrial, commercial and scientific purposes. Requiring education and understanding not only of mining principles and practices, engineers in this field are also expected to have an advanced and dynamic understanding of geological sciences, such as soil and mineral composition, surveying, prospecting and exploratory geological research. In addition to extracting the more conventional materials such as oil, precious and industrial metals and rarer gems and materials, many new advancements in information technology have expanded the role of geological engineering to search and mine for other materials, such as the dozens of special minerals and materials used in computer, tablet and smart phone construction.

At EducatingEngineers, we want you to understand the complexities of engineering careers and what it takes to succeed in your education. Please read the information below to learn more. And contact the schools in our directory to get started!

Employed by governments, major corporations, non-profit organizations and scientific/academic research institutions, geological engineers play pivotal roles in everything from industrial production of materials and energy, to advancing scientific understanding of the material composition of the Earth. Because of the numerous and varied functions for geological engineering and the substantial technological advancements made in the field itself, the role of the engineer in respect to mining and geological research continues to evolve, finding new and interesting applications for the science with each passing year.

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