Engineering Team Passes Full-Flight Qualification for F-16 Aircraft AM Spare Part in Just 30 days

• 分析与建模 - Generative AI
• 功能应用 - 制造执行系统 (MES)
• 功能应用 - 产品生命周期管理系统 (PLM)

• 航天
• 汽车

• 产品研发
• 维护

• 添加剂制造
• 预测性维护
• 数字孪生

• 软件设计与工程服务
• 系统集成

The U.S. Air Force’s Rapid Sustainment Office (RSO) held an advanced engineering competition. Teams were presented with some of the Air Force’s most pressing technical problems. This year’s challenge in the Approval Sprints category: produce a stronger, more durable hydraulic line clamp for the U.S. Air Force’s fleet of F-16 aircraft with Additive Manufacturing. The US Air Force has thousands of these hydraulic tube clamps in service across its fleet. The clamps fail after a certain amount of time due to exposure to vibrations, chemicals, and heat. For this reason, replacement parts must always be in stock. For full-flight qualification, the list of design requirements that the engineering teams had to pass within the 30-day time frame included: dimensional requirements, tubing retention, inertial loads, handling loads, flammability, temperature, freeze-thaw, vibrational loads, jet fuel exposure, hydraulic fuel exposure, engine oil exposure.

nTopology was founded in 2015 to enable engineers and designers to generate any geometry no matter how complex to meet the engineering requirements of high-performance products. Their award-winning software, nTop Platform, is used from research through production to create breakthrough processes and products for the aerospace, automotive, medical, and consumer industries. Their customers depend on nTop Platform’s generative design capabilities to take advantage of new hardware and optimize parts where performance is critical and overcome design bottlenecks by augmenting traditional CAD systems. In this case study, nTopology collaborated with Origin and Stress Engineering Services to redesign a family of F-16 aircraft hydraulic tube clamps for Additive Manufacturing, resulting in a part that was 2x the stiffness of the legacy design, easier to assemble, and manufacturable on-demand.

The new design consists of three parts: two clamp halves and a flexible tether. The two clamp halves were designed and optimized to maximize their performance. The clamp is able to carry double the load of the legacy design while being 5% lighter. It allows the clamp to be stored as one piece, enables fitting with one hand by the technician, and it is tearable after the installation. Material: Henkel Loctite 3955 flame-retardant, chemically resistant thermoset. Manufacturing: Over 1,200 units on-demand per day at a unit cost of $1.25. Traceability: Every part is serialized to ensure provenance and inventory management. The team focused on developing a methodology that could be easily replicated and reused to create libraries of high-performance 3D printable parts. First, they reverse-engineered the legacy clamp design to determine the loading conditions. Then, they used the nTop Platform’s topology optimization tools to determine and visualize the load paths. Finally, test samples of the candidate geometries were 3D printed in two different materials and tested in the lab under different conditions. When new information became available or when fundamental changes needed to be made to the design, the design engineers were able to generate new geometry simply by altering the inputs of their workflow in nTop Platform. This way, the team evaluated over 30 designs in 30 days.

• The new hydraulic clamp design is able to carry double the load of the legacy design while being 5% lighter.
• The clamp allows for easier storage and fitting with one hand by the technician, and it is tearable after installation.
• The team developed a replicable and reusable methodology to create libraries of high-performance 3D printable parts.

• Manufacturing over 1,200 units on-demand per day at a unit cost of $1.25.
• The new design is 2x the stiffness of the legacy design.