Flying High: Engineered Aluminium – Key to Lightweight, High-Performance, and Safe Aircraft

by R K Soni, CFO, Jindal Aluminium

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Aluminium is a remarkable metal that has revolutionized numerous industries over the past century, with the aviation industry benefiting the most. Its lightweight and exceptional strength make aluminium indispensable in ensuring that airplanes are safe, affordable, and feasible for transportation.

Aluminium has been a cornerstone of the aerospace industry since the Wright brothers’ first manned flight in 1903. They opted for aluminium to construct the cylinder block and other essential engine components, appreciating its lightweight and robust characteristics.

Since that historic flight, engineered aluminium’s role in aerospace has only grown, becoming a fundamental material in aircraft design and construction. Its exceptional properties have led to increased demand and numerous advancements in aviation technology.

Why Aluminium is Vital for the Aircraft Industry

The aerospace industry relies heavily on aluminium for two main reasons. Firstly, aluminium’s high strength-to-weight ratio makes it invaluable for constructing airframes that need to be both strong and durable to endure the stresses of take-offs and landings. Secondly, aluminium’s lightweight nature means it requires less fuel during flights, making it a more cost-effective material for aircraft construction. Thus, aluminium’s unique properties make it an essential component in the aerospace industry.

Aluminium’s advantages extend beyond its lightweight and strength properties. Engineered aluminium also boasts outstanding corrosion resistance, a crucial factor in enhancing the longevity of aircrafts. Planes are continually exposed to the elements and extreme conditions, such as freezing temperatures at high altitudes and various forms of precipitation, including snow and rain. Aluminium’s renowned ability to resist environmental corrosion makes it an ideal material for these harsh conditions.

Additionally, aluminium is highly formable, which is crucial for the aircraft industry that demands precision to ensure optimal aerodynamics and accommodate numerous small parts. Aluminium’s ease of fabrication and machining translates to cost savings compared to alternative materials. Furthermore, aluminium’s aesthetic appeal, though not the primary consideration, enhances the visual attractiveness of an aircraft.

Approximately 80 per cent of the metal content in contemporary aircrafts is made up of aluminium, highlighting its essential role in the aviation sector.

Diverse Uses of Aluminium in Aircrafts

Wings

Aluminium is extensively employed in the aviation industry, particularly in constructing the wing sections of an aircraft and other aerial vehicles. This preference is due to aluminium’s durability, lightweight properties, and ease of machining, making it a favoured material for ensuring the efficiency and performance of aviation components like wings.

Aircraft Cabin Components

Various components within the aircraft cabin, including tray tables, seats, and panels, are commonly crafted from engineered aluminium. Aluminium enhances the portability and longevity of these elements, ensuring durability and functionality throughout extended periods of use in aviation interiors.

Aircraft Fuselages and Components

Aluminium is widely utilized in constructing aircraft fuselages, prized for their robust strength, less weight, and resistance to corrosion. Beyond fuselages, numerous other components of air vehicles benefit from aluminium’s exceptional properties, effectively reducing the overall weight of aircraft and enhancing their performance.

Fuel Tanks

In aircraft manufacturing, engineered aluminium is frequently chosen for the production of fuel tanks. Its corrosion-resistant properties play a vital role in enhancing the durability and safety of these essential components, ensuring the integrity of the aircraft’s fuel storage systems.

Engines and Their Components

Aluminium plays a crucial role in the construction of aircraft engines and their parts. The metal is preferred for its strength and low density, making it an ideal for use in critical components such as casings, pistons, and cylinder heads. By reducing weight without compromising durability, aluminium helps enhance fuel efficiency and overall performance in aviation.

Key Aluminium Alloys Used in Aerospace

2024-T3

Alloy 2024-T3 is widely recognized as a high-strength aluminium alloy, particularly valued in aerospace applications. While its corrosion resistance is slightly inferior to that of 6061, it excels in fatigue resistance. This alloy is extensively utilized in manufacturing aircraft wing skins, fuselages, cowls, and structural components. Additionally, its polished surface makes it suitable for both original construction and repair work in aviation.

5052 – H32

This is a non-heat treatable alloy known for its exceptional strength within its category. Its excellent formability and workability make it particularly suitable for fabricating fuel tanks and other components requiring durability and resilience.

6061-T6

Grade 6061-T6 is distinguished by its impressive durability and polished surface. It has superior weldability and demonstrates strength comparable to mild steel. This alloy finds extensive use in aerospace for constructing landing mats and other structural components, owing to its exceptional fabricability using standard techniques.

3003-H14

It is renowned for its excellent workability and widespread application in various industries. Composed of pure aluminium alloyed with manganese, this non-heat treatable sheet can be easily deep drawn, welded, spun, or brazed. It is particularly favoured for crafting baffle plating and aircraft cowls due to its versatile manufacturing capabilities and reliable performance characteristics.

7075-T6

7075-T6 aluminium alloy is crucial for reinforcing aircraft structures with its exceptional strength properties. Formulated with precise proportions of magnesium, copper, and zinc, this alloy is engineered to provide enhanced strength and structural integrity. However, its copper content makes welding challenging, though not entirely prohibitive. Following anodization, it exhibits a sleek finish and offers superior machinability, making it a preferred choice in aerospace applications where strength and performance are paramount.

Conclusion

In conclusion, the future of aerospace technology will undoubtedly be shaped by the remarkable properties of engineered aluminium. Its lightweight yet robust characteristics have already revolutionized aircraft design and performance. As the industry continues to prioritize sustainability, the recyclability and efficiency of aluminium will play pivotal roles in developing environmentally friendly aircraft. Moreover, ongoing advancements in aluminium alloy research and development promise to yield even lighter, stronger, and more resilient materials, setting the stage for continued innovation and progress in aviation engineering.