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Case Study

3D Printing Breaks the Mould


Manufacturing outside the box.

Once innovation within a business takes hold, a domino effect of change often ensues. When Promolding, a Dutch specialist in global design, engineering, and manufacturing of high-tech plastic parts and components, ran up against customer requests for more complex products and faster turnaround, they realised the need to look outside traditional prototyping. Promolding specializes in creating high-tech plastic parts and components using high-performance polymer-based solutions for a range of market leaders, including Airbus and Heineken. Ensuring uncompromised quality and efficiency, especially in the early development stages, has been instrumental to the company’s success but customer needs weren’t static.

 

Serving the medical, aerospace and high-tech systems industries, Promolding, located in The Hague, Netherlands, realised additive manufacturing had the means to not only reduce lead times but add much-needed flexibility for rapid iteration during the design stage. Since then, not only has 3D printing advanced their immediate product development needs, but it has gone on to move them into a new territory traditional manufacturing hadn’t even allowed them to imagine.

Traditionally, injection mould development takes six weeks, but by designing and 3D printing the moulds in-house, we were able to produce complex versions in just three days.

3D printed fiber-optic sensor housings for Fugro.

Moulding the future.

Once clear on the benefits of the technology, Promolding purchased a Stratasys Connex3™ 3D Printer to facilitate their in-house prototyping applications. “Particularly with bigger and more complex product developments, it’s beneficial to be as quick and efficient as possible in the early development stages,” said Jeroen Gross, manager product development, Promolding. One of the company’s early successes with 3D printing came with Tigerfix, a glue solution for mounting bathroom accessories to walls without screws. Promolding 3D printed a glue cartridge to fit inside the metal plate, enabling the flow of glue to the individual parts of the mount. “The ability to print such a high resolution enables us to produce superior quality prototypes that closely match the final manufactured product,” said Gross. “This has been critical to optimising our design process and overcoming the complexities of polymer product development. We save approximately two days during product development by having our Connex3 Printer in-house.”

The next stage in Promolding’s 3D evolution came when product developers began to wonder if they couldn’t disrupt manufacturing altogether by 3D printing injection moulds. This provided the company the opportunity to offer its clients a whole new service, the rapid development of injection moulds for final product validation or further concept development. “Traditionally, injection mould development takes six weeks, but by designing and 3D printing the moulds in- house, we were able to produce complex versions in just three days,” said Gross. This venture resulted in a lead-time savings of 93% over traditional moulding for the company.


Promolding went on to develop fibre-optic sensor housings for Fugro, a world leader in integrated geotechnical, survey, subsea and geoscience services, which they were able to complete in a matter of days. Using one 3D printed mould of the complex, sensitive sensors, the team produced over 50 samples of the sensor housing in a number of final product materials.


Promolding’s 3D printing progression continues with the company’s latest innovation, Printed Injection Moulding (PRIM) operations. “PRIM will be available to our customers as an additional service in parallel to prototyping and traditional injection moulding,” said Gross. “Our state-of–the-art 3D printer has enabled us to achieve this and given us an incredible level of flexibility. We can use the technology to speed up the design process and develop, review and adapt prototypes earlier, but also extend the efficiencies into production through our PRIM process. It really has been a game-changer thanks to 3D printing and we’ve seen the benefits passed onto our customers.”

Promolding’s PRIM sensor housings.

Promolding, a specialist in design, engineering and manufacturing of high-tech plastic parts uses 3d printing for complex products and faster turnaround.

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