Whatever the size or type of aircraft, accurate assembly and structural alignment is essential to ensure efficient aerodynamic performance and safe operations throughout its service life.
Small aircraft and legacy manufacturing plants require simple and efficient tools to help operators handle and align fuselage sections together. Bigger aircraft or high-volume single-aisle programs are increasingly utilising automated assembly lines for fuselage to fuselage section assemblies or wing to body assembly, helping to reduce cycle times and keep up with demand for new aircraft. Hexagon Manufacturing Intelligence offers solutions to support all these requirements.
With aerospace components increasingly produced using distributed manufacturing methods, we provide equipment to not only inspect and verify the dimensional characteristics and features of aerospace parts, but also to set and verify jigs and fixtures, and even virtually simulate and assist operators with assembly.
The ability to fully-digitise complex parts allows manufacturers to compare the as-built aircraft assembly against the as-designed model using virtual assembly methods, ensuring best-fit between nominal and real part geometries. This enables early error detection in the manufacturing process, making it less costly to repair and ensuring rework takes place before the final airframe assembly.
Many aerospace manufacturers are also now using metrology-assisted assembly based on Hexagon Manufacturing Intelligence photogrammetry and laser tracker technologies to guide operators in the field and even to control robotics systems. Real measured data adds positioning accuracy to the high repeatability of standard industrial robots, enabling airframers to reduce production time for operations like wing assembly, stringer placement for fuselage sections, engine mounting and other aero-assembly functions.
Data analysis and visualisation tools help automate and improve the crucial identification, recording and analysis of aircraft structural damage from multiple sources.
Optimising the measurement of aircraft frames and stringers on the shop floor or close to machining centres increases productivity and ensures accuracy.
Portable measurement solutions can increase productivity in aircraft cabin fitting by simplifying the inspection of passenger seat frames.
The dimensional inspection of ribs, hinges and other large machined parts used in an aircraft’s structure requires large-volume measurement solutions with excellent...
Dimensional inspection of critical aerodynamic aircraft components such as winglets, fairings and pylons is essential to safe and efficient flight.
Accurate inclination measurement is required to calibrate and check the function of aircraft flight control surfaces such as the elevator, rudder, slats, flaps and ailerons.
Increase productivity by turning the installation and inspection of brackets in aircraft cabins into a one-step process.
Using 3D scanning to reverse engineer parts makes it easier to repair, maintain and overhaul aircraft for which CAD data is not available.
Airframers can test and measure the performance and durability of an aircraft structure’s movable parts more quickly and cost-effectively with simulation software.
Simulation software can be used to reduce development cycles by virtually testing CFRP components for the aerospace industry.
Aircraft manufacturers can improve the use and traceability of materials, as well as product design, by capturing, managing and sharing data about materials from within...
Cabin environmental conditions are essential to passenger experience, so designing an aircraft for the comfort of the people aboard is a priority for manufacturers.
Using acoustic simulation software to design quieter aircraft cabin interiors can have a huge impact on flight comfort and passenger experience.
Specialised acoustic simulation software enables aircraft manufacturers to reduce noise levels in the cabin and cockpit while using lightweight structural materials.
Engineers can shorten development times by using simulation software throughout the aircraft design lifecycle to analyse the impact of loads on its structure.
The complexity and cost of creating CFRP aircraft components mean manufacturers benefit from analysing and simulating the impact of manufacturing defects on part performance.