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09/10/2025 14:44

Additive Manufacturing for complex die casting tools

Petra Nolis M.A. Marketing & Kommunikation
Fraunhofer-Institut für Lasertechnik ILT

The Fraunhofer ILT and MacLean-Fogg have jointly produced a complex die casting tool inlay using Laser Powder Bed Fusion (PBF-LB/M). The specially developed L-40 tool steel enables the additive manufacturing of heavily loaded, large-volume tools for the first time and thus the implementation of conformal cooling. Initial results from smaller tools, which Toyota is already using in series production, indicate a significantly longer service life for the additively manufactured tools. In the current project, a hybrid, large-volume tool was created for the transmission housing of the Toyota Yaris Hybrid.

The combined process with conventional preforms plus additively manufactured structures shortens the production time, reduces costs and allows a high number of variants on a combined tool platform.

The automotive industry is in the midst of a profound upheaval. Cost pressure and the transition to electromobility are forcing many manufacturers to fundamentally rethink their vehicle architecture and production processes. Many manufacturers are currently reducing the number of individual pressed parts and striving for as few but highly complex structural components as possible. Particularly in the case of large aluminum components, such as frame or transmission components, this also increases the demands on the tools: they must be thermally highly resilient, allow variants and be able to be adapted to new geometries as quickly as possible.

This change brings with it new challenges: the required casting molds not only have to be larger than before, but also more resistant, with complex geometries and shorter development times. This is precisely where a project at the Fraunhofer Institute for Laser Technology ILT, together with the L-40 powder manufacturer MacLean-Fogg and Toyota as the end user, comes in.

By using a gantry-based PBF-LB/M machine developed at the Fraunhofer ILT with a scalable build volume and the tool steel developed by MacLean-Fogg for additive manufacturing, very large die casting molds with near-contour cooling could be additively manufactured for the first time - suitable for large-volume high-pressure die casting (HPDC) components.

Massive geometries previously led to residual stresses and critical defects in parts made with PBF-LB/M

As large casting processes are becoming increasingly established, the demands on the tools used in HPDC are growing. The molds must repeatedly maintain precise component quality at very high quantities and withstand extreme mechanical and thermal loads. In order to ensure a sufficient service life of the tool inlays, they need complex, internal cooling structures, which cannot be made with conventional manufacturing processes.

Two key problems have so far limited additive processes from manufacturing such large-format die casting molds: Firstly, the available construction volume of classic PBF-LB/M machines is too small to produce die or mold inserts with dimensions of 600 x 600 mm² or more in one piece. Secondly, the tool steels used to date – in particular H11 (1.2343), H13 (1.2344) or M300 – cannot be processed reliably in this size range (>20,000 cm³). Even with optimum parameters, there is a risk of cracking, thermal distortion and inadequate mechanical properties.

This applies both during laser-based build-up and during downstream heat treatment. The greater the temperature gradients within the component during the manufacturing process, the greater the risk - an effect that is particularly pronounced with large-volume workpieces.

"To overcome these limitation, we need a new generation of machines and materials specifically tailored to the requirements of large-format HPDC tools," explains Niklas Prätzsch, Group Leader LPBF Process Technology at Fraunhofer ILT. "It was precisely this combination that was the subject of the latest changes we have implemented."

The new material and machine technology makes it possible for the first time to produce large-volume tools with a free-form cooling structure. This not only allows local temperature peaks in the casting process to be reduced in a targeted manner, it also increases the number of variants while simultaneously increasing service life. This means that different components can be manufactured on one tool platform without having to produce new tools each time.

Scalable LPBF production for crack-free large components

The gantry-based 5-laser PBF-LB/M machine developed at the Fraunhofer ILT with a current build volume of 1,000 x 800 x 350 mm³ has been further developed for this purpose. In contrast to conventional systems, it has a movable processing head and local shielding gas guidance, so that the build volume can be scaled linearly along the machine axes with the same process boundary conditions (shielding gas flow speed, laser beam deflection angle, etc.). This means that even larger tools can be additively manufactured in the future than the tool inlay considered in this project with a volume of over 20,000 cm³ and a bounding box of 515 x 485 x 206 mm³.

A heatable substrate module was also developed in order to minimize the temperature gradients that are critical for large-volume tools. The build platform now reaches a temperature of 200 °C, which means that each new layer does not cool down to room temperature, but only to a predefined thermal plateau. This approach reduces thermally induced stresses and the risk of cracking during the construction process. The combination of large installation space, high process stability and active preheating makes this system one of the first LPBF systems in the world that is suitable for the economical production of near-net-shape die casting molds, even for mega or giga casting.

"The key to success lies in the L-40 material from MacLean-Fogg, which is tailored to the requirements of PBF-LB/M," comments Prätzsch. This steel is characterized by a significantly reduced tendency to crack compared to conventional tool steels - both during production and during heat treatment. Even in the as-built condition, L-40 achieves high dimensional accuracy, outstanding properties in terms of hardness (48 HRC), tensile strength (1420 MPa) and notched impact strength (>60 J). Comprehensive tests have successfully validated both the parameter transfer to the new machine concept and the performance in complex geometries - for example with round or overhanging cooling channels.

All in all, the combination of a scalable PBF-LB/M machine and a specially developed material enables the economical, reproducible production of large-format die casting molds with conformal cooling for the first time. Initial applications show that the service life of tools produced in this way can be significantly extended compared to conventional molds.

Hybrid production for series tool

As part of the project, the partners produced an additively manufactured tool insert for a gearbox housing that is already in use at Toyota. The die casting mold insert contains a complex network of near-contour cooling channels, which alone is a clear advantage of additive manufacturing that could not be achieved with conventional machining. For the additive tool design, the project team opted for a hybrid process on a specially manufactured preform that already had vertical cooling channels. The exact positioning and reliable connection of both components placed high demands on machine calibration, precision and process control. Such hybrid structures have the potential to further reduce construction time and costs, as the more cost-intensive PBF-LB/M process is only used in those component areas where conventional processes fail to work.

The researchers have designed the complex cooling structure in such a way that critical zones of the mold are effectively tempered during the die casting process. This reduces the thermal load, which significantly lengthens the service life of the mold. In previous projects, a comparable additive mold had already achieved a service life up to four times longer than a conventional H13 mold.

After the HPDC mold insert was built, it was stress relief annealed, and its functional surfaces were milled conventionally. The high dimensional accuracy of the additive base body only required precise final finishing without additional material input.

Paving the way for efficient and durable casting molds in the automotive industry

The production of large-format casting molds using additive processes addresses several key challenges in today's automotive production, particularly in the context of the transformation towards electromobility. A decisive advantage lies in the conformal cooling, which can be freely designed for the first time using 3D printing. The cooling channels can be optimally adapted to the thermally highly stressed zones of the tool. This lowers local temperature peaks, reduces thermomechanical wear and significantly extends the service life of the mold.

At the same time, additive manufacturing offers the opportunity to drastically shorten throughput times. Instead of time-consuming machining of several tool components and their assembly, a consolidated, end-to-end additive structure can provides substantial lead time reductions. For OEMs, this means shorter development cycles and faster time-to-market for new vehicle platforms.

The ability to build large-volume tools using hybrid technology creates additional flexibility. Components with defined interfaces can be efficiently added and functionally optimized without having to manufacture the entire component from scratch. This reduces both material usage and costs per tool.

“With L-40, we set out to break the limits of additive manufacturing for hot and cold forming tools in general and die casting tools specifically. This project proves that it’s possible to produce large, complex and highly durable inserts technically and gives clear miles stones to reach to be economically attractive. Additive manufacturing is ready to take on real industrial scale challenges. For OEMs, this is a game changer: shorter lead times, longer tool life and flexibility in tool design,” said Harald Lemke, Director of Product Management, MacLean-Fogg Component Solutions.

For vehicle manufacturers such as Toyota, who strive constantly for flexible manufacturing rely on fewer individual parts and more complex structures, these developments offer new possibilities in terms of tool strategy: less effort in tool production, longer running times and the possibility of realizing several variants with just one tool.

The manufactured component impressively demonstrates that the developed process chain - consisting of a large-format LPBF system, innovative material and hybrid production - meets the requirements of real industrial applications, even in the field of giga casting.

However, the potential extends far beyond the individual case: the developed process chain is not only suitable for large aluminum HPDC tool inserts, but also for applications in plastics processing or in the field of composite materials. Wherever heavily loaded tools with complex cooling and limited batch sizes are required, additive manufacturing can offer clear advantages.

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Contact for scientific information:

Niklas Prätzsch M. Sc.
Group LPBF Process Technology
Telephone +49 241 8906-8174
niklas.praetzsch@ilt.fraunhofer.de

Dr. Tim Lantzsch
Head of Laser Powder Bed Fusion Department
Phone +49 241 8906-193
tim.lantzsch@ilt.fraunhofer.de

Fraunhofer Institute for Laser Technology ILT
Steinbachstraße 15
52074 Aachen, Germany
www.ilt.fraunhofer.de

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More information:

https://www.ilt.fraunhofer.de/en.html

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Successful joint project between Fraunhofer ILT, MacLean-Fogg and Toyota: A Laser Powder Bed Fusion ...

Copyright: ©Toyota Europe.

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The additively manufactured aluminum die-cast tool is part of the tool for the transmission housing ...

Copyright: ©Toyota Europe.

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Criteria of this press release:
Business and commerce, Journalists, Scientists and scholars
Materials sciences, Mechanical engineering
transregional, national
Cooperation agreements
English

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