The Benefits of Titanium Hot Forming in Aerospace Applications

The Benefits of Titanium Hot Forming in Aerospace Applications

By Bill Carson  |  May 1, 2024

Titanium, known for its exceptional strength, corrosion resistance, and high-temperature performance, plays a pivotal role in the aerospace industry. When combined with the hot forming process, titanium’s strength as a material is coupled with the capability to be formed into more complex shapes than with other forming methods, offering unparalleled benefits for aerospace applications. Here, we’ll discuss those benefits further and outline how titanium hot forming for aerospace products is the preferred manufacturing method for discerning part and assembly providers.

The Importance of Titanium in Aerospace

Titanium is a gold standard in aerospace materials, thanks to its outstanding strength-to-weight ratio, unparalleled corrosion resistance, and superior performance under high temperatures. When juxtaposed with traditional aerospace materials like aluminum, titanium’s advantages become even more pronounced. For instance, with a low thermal expansion rate, titanium doesn’t change shape significantly with temperature changes — ensuring stability and precision in sensitive applications.

Titanium was discovered in the late 18th century but remained a laboratory curiosity until the early 20th century due to difficulties in extraction and processing. It was initially used in military applications, such as in armor and naval ships during the Cold War era, due to its strength and resistance to corrosion. The introduction of jet engines in the mid-20th century marked a turning point for titanium in aerospace. The metal’s ability to withstand high temperatures without losing strength made it ideal for jet engine components, leading to its increased use in military and then commercial aircraft. Today, titanium is not just used for structural components and engines but also in landing gear, hydraulic systems, and increasingly, in the fast-growing sector of commercial space exploration.

Overview of the Hot Forming Process

Hot forming, a process where metal is shaped at elevated temperatures, reduces the force required to form complex shapes because of titanium’s enhanced ductility at elevated temperatures. This method stands in contrast to cold forming techniques, which, while beneficial for certain applications, do not provide the same level of formability for materials like titanium. The hot forming process enables part shapes unattainable through cold forming with production benefits such as:

  • Increased accuracy due to the elimination of springback
  • Easier forming of complex shapes with tighter radii
  • Reduces the chances of cracking, especially when forming titanium

Critical Benefits of Titanium Hot Forming Aerospace Applications

1. Design Flexibility and Complexity

The malleability of titanium at high temperatures allows engineers to push the boundaries of design, creating complex shapes and intricate designs previously unattainable. This flexibility reduces the reliance on mechanical joints — which add weight and potential points of failure — resulting in structures that are both lighter and stronger.

2. Cost Efficiency

The process of hot forming a part from titanium sheet metal is typically a less expensive process than constructing the part through CNC machining from a block of the material. The method also allows for the exploration of new potential parts to be made of titanium, which previously were too cost-prohibitive to produce through machining but might be more viable with the hot forming technique.

3. Quality and Precision

Titanium hot forming is synonymous with excellence in dimensional accuracy. The consistency in production it offers ensures that aerospace components are reliable and meet the stringent standards of the industry.

Re:Build Cutting Dynamics Leads the Way in Titanium Hot Forming for Aerospace

The combination of titanium and hot forming represents a significant leap forward in aerospace manufacturing, offering a blend of performance, efficiency, and design flexibility that is hard to match. As the aerospace industry continues to evolve, the demand for lighter, stronger, and more reliable components will undoubtedly keep titanium hot forming at the forefront of manufacturing innovation.

Now a part of Re:Build Manufacturing, Re:Build Cutting Dynamics is dedicated to pushing the boundaries of what’s possible with titanium, harnessing the power of hot forming to create components that are technologically advanced. Our hot forming press, which operates at up to 1,600℉, uses several advancements to optimize the process:

  • 30” x 48” heated platens fabricated TMA® 4505 – a high-strength, heat-resistant alloy developed specifically for high-temperature applications
  • Door systems that are insulated and automatically actuated, which efficiently contains heat within the forming chamber and allows access during part or tool loading and unloading
  • Structure engineered to the Infinite Life classification using finite element analysis (FEA) design software

For nearly 40 years, Re:Build Cutting Dynamics has focused on providing unmatched value to customers in need of anything from our extensive list of aerospace manufacturing capabilities. Our established system of measurable objectives, industry-leading technology, and continual improvement deliver results that have allowed us to work with some of the biggest brands in aerospace.

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A Comprehensive Guide to Aerospace Hydroforming

A Comprehensive Guide to Aerospace Hydroforming

By Bill Carson  |  May 1, 2021

Hydroforming is a unique and versatile metal forming process widely used in the aerospace industry for its ability to produce complex shapes with a single tool, in a single setup., complex shapes with excellent structural integrity. Below, we’ll embark on an exploration of aerospace hydroforming, shedding light on its processes, applications, materials, and the recent advancements that underscore its crucial role in aerospace manufacturing.

Understanding Hydroforming

At its core, hydroforming is a technique that uses high-pressure hydraulic fluid to shape metals into precise, complex configurations. This method is especially beneficial in industries where the strength-to-weight ratio is a critical factor, such as aerospace. This production process is an excellent choice for high-mix, low-volume (HMLV) manufacturing—producing a high variety of products in small quantities.

There are two primary types of hydroforming: sheet hydroforming and tube hydroforming. Sheet hydroforming involves pressing a metal sheet into a cavity die or over an external die using a high-pressure hydraulic fluid. Tube hydroforming expands a metal tube into a desired shape using the same fluid pressure technique. Both processes offer distinct advantages, but sheet hydroforming in particular is prized for its ability to easily form compound contours with varying bend angles. Hydroforming accomplishes this without the need for expensive matched-metal die sets often seen in stamp forming.

The Role of Hydroforming in Aerospace Manufacturing

Aerospace manufacturing sets a high bar for part precision, strength, and weight. Hydroforming meets these stringent requirements by enabling the production of complex shapes that—when used with the appropriate material— are both light and strong. Applications range from structural components, such as fuselage frames and wing ribs, to smaller, intricate parts like ducts and brackets and critical elements such as engine parts.

Materials Used in Aerospace Hydroforming

Material selection is crucial in aerospace hydroforming, with aluminum and carbon steel being among the most commonly used due to their favorable properties, such as malleability and strength. Expert-level facilities and partners can also hydroform additional materials, such as stainless steel.

Each material’s characteristics, including formability and resistance to stress and corrosion, play a significant role in determining its suitability for specific aerospace applications. While all these materials are ideal for the high-stress environment of aerospace applications, offering the perfect balance between durability and weight reduction, you should collaborate with your aerospace manufacturing partner for specific material recommendations.

Aerospace Hydroforming Process, QA, and Challenges

The aerospace hydroforming process begins with careful planning and design, followed by the selection of suitable materials. The actual forming process involves placing the metal blank into the hydroforming press, in which the sheet metal is forced to take the shape of only a single rigid die by the action of fluid pressure — which acts through a rubber diaphragm.

One key advantage of this process is that only a single rigid die is needed, making it possible to form more complex shapes wrinkle-free and with material thinning as low as 10%. The complexity of the shape and the material chosen will also affect the rate of thinning.

Once the press operation has completed, subsequent steps such as trimming, heat treatment, and finishing processes can be employed to further enhance the part’s properties and appearance. Quality assurance is the final step, and one of the most important.

Quality and testing are paramount in aerospace hydroforming given the high stakes for the end product and industry. Stringent controls and certifications are a must in the industry to ensure every component meets the highest standards of safety and performance.

Hurdles to Clear

Challenges such as cost, material limitations, and the need for specialized equipment and expertise can pose significant hurdles. Recent innovations in hydroforming technology, such as improved hydraulic systems and computerized control software, have significantly enhanced the efficiency and accuracy of the process, but have added complexity. This underscores the importance of partnering with experienced and innovative hydroforming specialists capable of navigating these issues.

Experience Expert Hydroforming for Aerospace with Re:Build Cutting Dynamics

At Re:Build Cutting Dynamics, we’re proud to stand at the forefront of aerospace hydroforming innovation. Our extensive capabilities in aerospace manufacturing and our position within Re:Build Manufacturing position us to tackle the most demanding projects.

We understand the important role our parts play in the aerospace industry and we’re committed to upholding high-quality standards. Our dedication to quality is proven by our certifications in both AS9100 and ISO 9001:2015. We provide complete traceability of every component by maintaining a digital record and certification system for parts.

Re:Build Cutting Dynamics has more than 15 years of experience in hydroforming; We integrated our first hydroforming center in our Avon Lake, Ohio facility in 2008. Our in-house tooling capabilities combined with the redundancy of multiple presses enables us to offer a large production capacity for a faster response to client needs. Our team also specializes in low volume production, which means we can perform smaller run production of components with distinctive efficiency.

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