(Nikon Metrology NV: Leuven, Belgium) — Nikon Metrology and Magestic Systems Inc. jointly introduce an innovative fabrication solution for increasing production of right-first-time composite parts that harnesses the vast capabilities of both Nikon Metrology’s laser radar technology and Magestic Systems’ Ply Compensation System (PCS).
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The synergy between Magestic Systems’ PCS and Nikon Metrology’s laser radar offers composite part manufacturers a seamless solution—utilizing metrology, ply nesting, and laser projection technologies to produce composite parts within engineering tolerances thus achieving minimal waste. By combining laser radar and PCS technologies, manufacturers put in place an automated metrology-assisted production process that delivers parts of predictable quality, while rigorously reducing scrap, and maintaining accuracy, scalability, and ease of use. Despite their generally high cost, composite materials have gained popularity in high-performance products that need to be lightweight, and at the same time strong enough to take harsh loading conditions. Today, composite materials are widely used in aviation components (tails, wings, fuselages, propellers), space vehicles, boat hulls, race cars, storage tanks, turbine blades, and even baseball bats.
Production issues
Traditional production methods, which have become standards for steel and aluminum industrial production, will not suffice for serial production of composite parts. A variety of factors often prevent manufacturers from keeping geometric deviation within specification, whether it is the nature of combined composites’ substrate, resin, and reinforcement materials, or even the method by which the parts are molded. Low process repeatability generates lengthy manual rework and an intolerable number of failled components that end up on the scrap pile.
PCS process offers unique alternative
“As a full-scale enterprise solution, Magestic Systems’ Ply Compensation System provides a unique alternative to the current machining process for composite part fabrication,” says Mike Weber, Magestic vice president of operations and business development. “PCS takes parts that have been produced slightly outside of engineering tolerances, and builds them up by single or multiple composite compensation ply layers into finished parts that satisfy all structural and engineering requirements—the first time through the production process. This revolutionary method ensures that as-built composite parts adhere to as-designed specifications, while reducing material usage and improving efficiency.”
The process starts with identifying those surface areas on composite parts that need compensation ply treatment.
“Within a range of 60 meters, the contactless laser radar system from Nikon Metrology [formerly Metris] captures the surface geometry of composite parts of any shape and size, without requiring SMR [spherically mounted retroflector] or other targets”, explains Francky Demeester, Nikon Metrology vice president of business development for large-scale metrology. “The laser radar is fully automatic, programmable, and measures nominal deviation very accurately, both in plane- and surface-vector intersection modes. Plane-vector intersection measurements have shown an order of magnitude improvement in measurement accuracy over other single-point measurement systems, in particular on composite materials. The integration of laser radar into innovative manufacturing methods illustrates the effect of metrology-assisted production on composite part production quality and throughput.”
Based on the laser radar’s geometry data and the resulting nominal deviation of the tool surface, Magestic Systems’ PCS manages the definition and creation of multilayer compensation plies. After processing this critical step, Magestic Systems’ TruNEST builds nests of the necessary compensation plies and automatically cuts them out to be laid up. TruLASER View kits the compensation plies while still on the cutting table and projects the exact location of where on the deficient part they need to be placed, keeping all grain constraints in mind. Following this, the part is then ready to be recured to obtain final geometry. The finished composite part is then measured again with laser radar for geometry deviation. By producing composite parts correctly the first time, immediate savings can be noted in the minimization of waste and the maximization of accuracy, part quality, and process efficiency.
“Our focus with the development of this application was to provide a solution that integrated the unique capabilities of both Nikon Metrology and Magestic Systems to best-fit industry needs,” concludes Weber. “With the current state of the world economy and the rising costs of composite materials, we put a premium on cost efficiency to complement the unique capabilities of this breakthrough solution. All its economic and quality benefits ensure a positive bottom-line return on investment for world-class manufacturers around the globe.”
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