Flow International Corp.’s Composites Machining Center (CMC) hits the mark for single-setup processing of 40 m-long composite wing skins. One of the keys to holding long axis accuracy during week-long machining cycles is Renishaw’s HS10/HS20 laser encoder. Measuring distance with the precision of a laser interferometer, the encoder and its companion RCU10 real-time compensation unit, deliver part-per-million positioning accuracy on the CMC’s X axis. The laser encoder eliminates variables that had to be compensated for when using a physical scale attached to the machine.
Flow’s CMC is one of the new machine tools developed to meet the aerospace industry’s need to produce large monolithic parts with minimal dimensional variation. “Reduced variation in parts is an industry wide goal,” said Mark Saberton, Flow’s Director of Aerospace. “The objective is reduced assembly time, effort and tooling. The OEMs want to eliminate assembly shimming, which adds weight to the product and time to the process. They want parts to meet tolerances when they arrive on the assembly floor, rather than using fixtures and shims to bring parts into assembly tolerance. Weight is also an issue. Less variance on a plane’s parts ensures better control of the aircraft’s final weight.”
The CMC was created as a one-stop processing center for autoclaved composite parts. It can be configured as a mid-rail gantry or dual travelling column machine. The gantry design carries two rams on a single gantry with a 5-axis wrist on each ram, one for ultra high pressure waterjet cutting and one for conventional high-speed routing. The CMC can do all the finish machining on a wing skin: trimming, drilling, routing, surface milling, marking and inspection – in one setup, and parts leave the machine ready for assembly. The machines are widely used by Airbus partners around the world.
The modular CMC is available in standard X axis lengths of 6 to 50 m, as well as custom sizes. “We had always used tape scales on the X axes, but a physical scale 30 to 50 m long, attached to the machine, introduces structural issues and makes thermal compensation much more difficult,” said Todd Fuchs, Senior Electrical Project Engineer at Flow. “The temperature differences the machine sees over a 40 m length during a 130-hour machining cycle can be relatively extreme, even in an air conditioned plant. Between changes in the scale itself and the substrate of the machine, the variables become too complex. The HS20 laser encoder is the easiest way to obtain accurate feedback on such a long axis.”
With a rack and pinion drive on each side of its gantry, the CMC uses split X axis feedback with a laser on each side, working as a master and slave for positioning. The lasers are located under the way cover bellows near the drivetrain, in a duct purged with clean, dry air, ensuring stable measurements and protection from airborne debris that might “break” the laser beams.
Flow has used HS10 laser encoders and its successor HS20 on a total of 24 machine axes. Both encoders use the same laser interferometry technology used for linear error measurement and compensation by machine calibration specialists, except the laser encoders are designed to be a permanent scale on the machine, replacing glass/tape fitment and resolvers.
Unlike a tape or glass scale, the laser encoder system has no short-term errors which can “stack up” on long axes, and its 1 m/sec measuring speed accommodates today’s fast-moving machine tools. The HS20 is sealed to IP43 and hard anodized to provide all round protection in harsh machining environments. “Our X axis repeatability spec for a 40 m gantry is 0.0381 mm (0.0015 in.), essentially equal to the laser interferometer used to calibrate the machine,” said Fuchs. “The laser also provides twice the resolution of a tape scale, though a machine of this size and type is unable to make use of it.”
X axis positioning precision is also a factor during part probing, which is vital to the cutting process. The CMC uses a Renishaw RMP60 touch probe for locating the part during setup and confirming finished dimensions after machining. “Some of these parts, such as wing skins, are worth nearly $1 million before machining,” Fuchs stressed. “When they come to the machine, they are seldom a match to the CAD model, so we probe extensively and do a lot of best fit calculations prior to machining.”
The touch probe’s compact design allows it to access and measure any point on the part that the machine head can reach. Its frequency hopping spread spectrum (FHSS) radio signal transmission allows multiple probe systems and other industrial equipment to coexist in “noisy” industrial environments, particularly as wireless Wi-Fi and Bluetooth communications proliferate. “We have laser equipped machines in many European countries already, and the Renishaw HS20 laser encoder has proven easier to deploy than tape scales, as well as reliable and robust,” Fuchs adds. “For these long axes, where machines are cutting expensive and critical parts, customers appreciate X axis positioning that’s as accurate as the gold standard of linear measurement, the laser interferometer.”
Filed Under: TECHNOLOGIES + PRODUCTS, Design World articles, Lasers