Custom Machines Create Engine Lip Skins on Boeing Aircraft

MJC Engineering, a custom machine tool builder in Huntington Beach, CA, specializes in metal-spinning machines for such applications as sheet spinning, flow forming, wheel spinning, and rotary forging. The company was commissioned to build a series of metal-spinning machines for GKN for use at its plants in Camarillo, CA and Orangeburg, SC. These machines produce lip skins for the engine housings on Boeing 777X and 737MAX aircraft. Using CNC from Siemens Industry (Elk Grove Village, IL) and robotic handling technology — in addition to its proprietary servopump-controlled Green Power™ hydraulic power unit that saves up to 40% on energy — the MJC team devised a unique solution to an engineering challenge brought to them by GKN.

The machine designed by MJC Engineering forms 270”-diameter aluminum sheets, typically 5/8” thick, into lip skins for the nacelles on the engines of Boeing 737MAX and 777X aircraft.

The key aspects of the solution comprised how to spin-form production-run components out-of-round by 8½" to 9" in various aluminum alloy blanks measuring up to 270" diameter and 5/8" thickness, while holding tight tolerances to be verified by thermo-imaging cameras and fed back by the CNC for accuracy tracking. The solution also had to integrate the heating torch for in-process adjustments.

Combining Old and New

Each day, the MJC team combines the same metal-forming process that has been around for millennia with modern CNC controls and robotics to create the state-of-the-art manufacturing process used to produce laminar flow lip skins for Boeing’s newest flagship 737MAX and 777X aircraft. The lip skin is the highly engineered aerodynamic structure that makes up the leading edge of jet engine nacelles.

Metal-spinning is a forming process in which a blank of material is rotated on a spinning machine similar to a lathe. The blank of material is clamped onto a spin-forming mandrel and rotated by servo-controlled motors and drives. During rotation, heat is applied by a gas torch affixed to a robotic armature, and a roller on the spinning machine makes contact with the part blank, forcing the part blank to flow over the spin-forming mandrel surface.

Siemens Sinumerik 840D sl CNC — along with Sinamics drives, Simotics motors, and Simatic PLC — control the seven axes of motion on the machine and the 32 programmable movements of the robot, to which the heating torch is affixed.

Spin-forming, like no other metal-forming process, has the ability to form very large and thick plates quickly and accurately. Though highly efficient in operation, the 737MAX and 777X CNC metal-spinning machines built by MJC and currently located at GKN, are reliant upon the precise and consistent application of heat throughout the metal-forming cycle. Even the slightest variation in heating would contribute to undesirable results in the formed part.

Until recently, manufacture of these lip skin components relied upon human intervention to control the direct application of heat throughout the spin-forming cycle. While this method could certainly produce a functional part, the associated variations in part consistency created downstream difficulties and challenges in subsequent fabrication and assembly operations. In the past, lip skins were produced by other methods, including draw-forming, bulge-forming, and drop-hammering. The spin-forming and machining techniques now used at GKN have been found to reduce overall manufacturing time and tooling costs, while improving part consistency.

In an effort to reduce variation in the CNC spin-forming process to support high-rate programs such as the 737MAX and 777X, GKN Camarillo joined forces with MJC Engineering to create an automated CNC solution. That solution is now a reality, and consists of robots that apply heat in a precise and absolutely consistent manner, tied directly to a program that shapes the part. This careful interplay between the heating and spin-forming operations is made possible by the Siemens Sinumerik 840D sl CNC, which integrates and monitors every movement between the spinning machine controller and the heating robot controller, resulting in a smooth-flowing production scenario.

Increased Predictability

A CAD illustration depicting the machine in operation, with worker shown for size relationship.

Before this combination, variation in product output was much less predictable. But today, part heating difficulties and variations are a thing of the past. CNC spin-formed lip skins with automated robotic heating exit the process as consistently as a stack of quarters, to draw an analogy. The results are derived from straightforward mathematical computations made possible by modern CNC technology from Siemens.

In operation, the machine takes the overhead crane-loaded 270"- diameter blank, fixes it to the tailstock of the machine, and rotates it on a 150-HP motor-driven spindle, then progressively applies heat via the gas torch on the robot arm. Raytek thermal imaging cameras closely monitor the heat readings over the entire surface to create multiple control cones. When inconsistencies are detected, the heat is appropriately adjusted in real time by the controllers. The heated material is then formed over the mandrel into the desired size, with out-of-round conditions typically ranging from 8½" to 9". Siemens Simatic S7 PLC technology is onboard the machine, controlling the various mechanisms, while the CNC integrates and feeds back all data.

This view of the machine shows the MJC Engineering Green Power™ hydraulic unit on the far left.

The Solid Edge CAD program is used for the design of the lip skin, while Siemens NX CAM translates the design data into machine execution steps. Each MJC machine involved in this project also incorporates Sinamics drives and Simotics motors from Siemens. There are seven axes of motion controlled by the CNC. Custom screens were created for teach-in and playback on the machine to facilitate faster commissioning and troubleshooting onsite for the GKN operators. Zone Pro and Spin CAD were used to create the tool paths. On the robot, there are 32 pre-programmed moves, fully integrated with the heating and thermal imaging processes. The robot runs with an external PLC through G-code on the CNC, which dictates the on/off heating and cooling controls, based upon feedback from the temperature zones monitored.

The company was able to provide its proprietary Green Power technology and, in the process, saved the customer substantial energy costs. The advantages of the machine design ratcheted up to a great degree. Using Sinamics servo-pump technology, Green Power provides exactly the hydraulic pressures needed, offering the customer energy savings up to 40%, compared to a conventional “constant on” hydraulic pump motor manifold.

For more information on the Siemens products used in this application, visit http://info.hotims.com/61068-322 .