MOULD MAKING PETplanet Insider Vol. 26 No. 04/25 www.petpla.net 22 Smart prototyping: De-risking bottle design with data-driven insights Why speed alone isn’t enough In the world of fast-moving consumer goods (FMCG), brands and converters operate under immense pressure to launch new packaging quickly. Rapid prototyping has become an industry norm, yet simply producing a bottle faster is no longer enough. Advances in virtual simulation, 3D-printed moulds, and lab-scale testing are reshaping how bottle designs are refined and optimised, ensuring better performance and reducing risks before mass production begins. BMT’s method of a data-driven approach to bottle development combines virtual simulation, 3D printed moulds, and lab-scale stretch blow moulding. Their methodology - measure, digitise, execute - focuses on gathering insights rather than relying solely on iterative testing. By capturing critical information about material behaviour, blowing dynamics, and final bottle performance, the design process can be refined, reducing lead times and mitigating risks associated with production. Engineering confidence before production begins At the core of this approach is BMT’s proprietary SBM simulation, which uses advanced material models to virtually assess the preform to bottle design before any physical prototype is made. This allows engineers to predict bottle formation, identify areas for optimisation, and verify performance virtually - long before production tooling is considered. By making smarter decisions at this stage, costly modifications down the line can be avoided. Advanced testing capabilities Using Blowscan, BMT’s lab-scale SBM machine, small batches of bottles are produced under controlled conditions. Integrated with Thermoscan technology, the full temperature profile of the preform is captured. Simultaneously, pressure data and material distribution are tracked in real time, providing a detailed picture of exactly how the bottle is formed. This level of analysis provides engineers with precise information to optimise preform geometry, material selection, and processing parameters for efficient scale-up. 3D-printed mould tools Traditionally, creating prototype bottles required expensive metal mould tools and access to an industrial SBM machine, adding time and cost to the development process. By 3D printing the mould tool, BMT reduces the time from concept to prototype from weeks to days. The tooling is designed to work seamlessly with Blowscan, so engineers can test and iterate designs rapidly, all while generating performance data that informs final production decisions. Performance validation To assess the viability of 3D printed mould technology, BMT conducted a comparative study, forming two sets of bottles using the same blowing recipe – one from a 3D printed mould, the other from a traditional metal tool. The results confirmed equivalency across all critical parameters. Geometrically, both botMOULD MAKING MON TUE WED THU FRI BMT OUTPUTS Physical Bottles Process Qualification Performance Qualification SIMULATION PRODUCTION Build Simulation Virtual Investigation Define Process Window Mould Design Mould Print Mould Build Process Qualification Bottle Production Physical Validation 3D PRINTING CLIENT INPUTS Preforms Bottle Design
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