If you’re interested in working in the aerospace industry explore more about Aerospace parts manufacturing company Danbury CT, there are many benefits to establishing an automated production facility. This increases efficiency and productivity, but the industry is also very growing, as the number of private aircraft owners and business airlines has skyrocketed. As a result, the demand for aerospace parts has risen significantly. You may have been wondering how to start a career in this industry. Read on to learn more about what’s involved in this field.
Work environments in aerospace manufacturing facilities
The working environment at aerospace manufacturing facilities varies wildly. Some are well-lit and spacious, while others are cramped, dark, and overly humid. The specific environmental conditions required for each type of production process may depend on the worker’s occupation and the age of the production line. For example, engineers and scientists often work in offices, while production engineers spend much time on the factory floor. These employees may be exposed to high noise levels, oil, grease, grime, and other elements that pose health risks.
The human factor is directly linked to burnout and the decline in the quality of labor. According to Shanmugam and Robert, up to 90% of aircraft maintenance and manufacturing errors are directly related to human factors. In addition, the authors highlight several significant activities that contribute to an industry culture that promotes a high standard of labor and quality. They emphasize transformational leadership as a way to change a company’s culture. Ultimately, these practices promote employee engagement and retention.
Common materials used in aerospace manufacturing
Aluminum is one of the most popular metals used in aerospace manufacturing. It is extreme yet lightweight and is known to have the smallest amount of carbon content. It is also resistant to corrosion and is used in a variety of aerospace components and engines. Titanium is another popular metal used in aerospace manufacturing, as it is naturally corrosion-resistant but can be alloyed with iron or manganese to increase its strength and lightweight.
High-temperature materials are also used in aircraft production. These materials are able to withstand high temperatures and are flexible, making them ideal for many aerospace applications. For example, ceramic matrix composites are lightweight yet incredibly tough and are used in engine components to improve the structural performance of aircraft. They are also less brittle than nickel superalloys, so they are difficult to work with while still maintaining their structural integrity. But despite their weight, many aerospace components are made with these high-performance materials.
Management, business, and financial occupations
Aerospace workers are needed for many different jobs, from engineers to accountants. Besides machining, the aerospace industry requires input from scientists, engineers, and technicians. In addition, workers in computer and mathematical science occupations are needed, and Federal record-keeping laws must be followed. These professionals are often required to have at least a bachelor’s degree in aerospace. Management, business, and financial occupations are among the highest-paying jobs in the industry.
This industry has its distinct production cycles, not necessarily following those of other sectors. Job openings increase quickly when significant new systems and aircraft are under development, decreasing rapidly once the production run has ended. The best time to work in the aerospace parts manufacturing industry is when new aircraft and spacecraft are in production. The aerospace industry has a strong demand for these parts, and the job market is high, so those seeking a career in this field should plan accordingly.
Non-traditional manufacturing processes
The introduction of PCE is changing the aerospace industry by replacing the concept of “over the wall” product development. Different departments work together to achieve the desired design quickly and cost-effectively with this approach. With PCE, design changes can be made with minimal cost and without the need for tool steel recutting. This method also has several advantages over traditional manufacturing processes. For example, it has been shown to decrease the time required for a product to reach its manufacturing stage and ensure the quality and precision of the finished product.
CNC milling, laser machining, and electrochemical machining are just some non-traditional manufacturing processes available. The aerospace industry requires precision and durability for many parts, and traditional machining techniques may not be sufficient. This method uses energy to process the material directly and reduces waste materials. Furthermore, it boosts production efficiency and increases machining accuracy. Non-traditional manufacturing methods like machining using power also increase the cost-efficiency of production.