Aluminum Alloys: Go-to Materials for Automotive, Aerospace, and More
Aluminum is a common and popular metal that’s found everywhere and used in a stunningly wide range of parts and products: automotive parts, aerospace components, boat and marine gear, consumer electronics including smart phones, industrial machinery parts, HVAC systems, the list goes on.
Engineers and product designers frequently turn to aluminum and many of its alloys to design both prototypes and end-use parts in a variety of industries. This post takes a look at why aluminum is so common, why there are so many aluminum alloys, and takes a brief glimpse at the main alloys we use here at Protolabs.
Why is Aluminum So Popular?
Aluminum has a high strength-to-weight ratio, making it lightweight, yet strong and flexible. It’s also affordable, corrosion-resistant, and works well in a multitude of applications.
Aluminum alloys are often used in cars because of the material’s versatility. Aluminum’s formability and corrosion resistance make it easy to work with and shape, but its structural soundness addresses the most important requirement for car bodies. Strength is important, but car bodies must be lightweight, affordable to produce, resistant to rust, and have the attractive qualities consumers seek, such as exceptional surface finishing characteristics. Aluminum nicely fits the bill.
The same holds true with aerospace parts. Aluminum alloys are often a preferred material for aerospace designs and required by engineering, again because of aluminum’s corrosion-resistance properties and high strength capabilities. Compared to steel it is a lightweight option, and an ideal material for a wide range of aircraft components and aerospace applications.
Lightweighting is a core need of both the automotive and aerospace industries.
With cars, lightweighting helps reduce emissions and meet improved fuel economy standards.
For aerospace, the use of aluminum alloys dramatically decreases the weight of an aircraft because it is significantly lighter than steel, allowing aircraft to either carry more weight or increase fuel efficiency. For instance, a 20% weight reduction in a Boeing 787 is expected to generate a 10–12% improvement in fuel efficiency. Along these lines, common applications in aerospace abound—many, but not all, of which, are metal: Fuel nozzles, heat exchangers, manifolds, turbo pumps, liquid and gas flow components, conformal cooling channels, fasteners, and more.
Why So Many Metal Alloys?
Aluminum, as a pure element, presents many desirable properties. However, by itself, aluminum might not be strong enough for a high-durability use or purpose. Accordingly, aluminum can be combined with other elements to form alloys, which are more durable and suitable for industrial applications.
And what do all of those numbers in the alloy name signify? The aluminum series names elements with four numerical digits where the first digit represents the principal alloying element, the second digit indicates a modification of a specific alloy, and the third and fourth digits are arbitrary numbers assigned to specific alloys in the series.