Machine Launch Announced For NeuBeam AM With Embedded Process Monitoring
The rate of uptake of metal AM is not as fast as many predicted even just a few years ago, because AM — particularly when using metal — comes with a number of limitations.
Wayland Additive has been working on the development of an entirely new powder bed fusion (PBF) process for metal AM that minimizes the existing limitations that current users have to work around. When considering the existing two PBF technologies namely laser PBF and traditional eBeam PBF. NeuBeam® offers a new way, a third way.
Embedded Process Monitoring
Wayland Additive has recently announce that it will be commercially launching its first NeuBeam production system, Calibur 3, in January 2021 with shipment commencing later in the year. Designed specifically for production applications, the Calibur 3 incorporates fully embedded in-process monitoring capabilities that provide full oversight during every build and ensures full traceability for every part.
PBF is arguably the most widely adopted AM process for structural production applications. To date there has been a clear two-way choice with PBF, users either having the option to use laser-based PBF systems or eBeam PBF technology.
One trade-off between the two technologies comes down to precision versus speed. While laser PBF has traditionally held the advantage in terms of fidelity and surface finish (due to the precise nature of the laser(s), eBeam PBF gains significant advantage in terms of speed and productivity as a result of the more efficient way that electrons transmit energy to the powder bed, and through-thickness heating of the entire layer. In addition, eBeam can process multiple meltpools simultaneously, further contributing to increased productivity.
Will Richardson, Co-Founder and CEO at Wayland Additive says, “It is no secret that existing Laser and eBeam PBF systems come with limitations, some of them prohibitive. With Laser PBF, the internal residual stresses that the process generates requires extensive structural supports to prevent the parts distorting or cracking during the print process. Sometimes these supports require as much material to manufacture as the parts themselves. Removing them post-build typically requires the use of wire EDM and machining operations, which are expensive and time consuming. The parts typically also require stress-relieving in a furnace post-build – another operation, more cost, and another piece of equipment to maintain and run.”
Peter Hansford, Business Development Director at Wayland continues, “The traditional eBeam PBF process faces its own challenges and constraints, most notably the instability of the process caused by charge accumulation within the build chamber. This can result in powder scattering or a so-called “smoke event” that distorts the current layer of the build and therefore compromises the entire build. To avoid this, the process has to be operated in a very specific way, and has a steep learning curve. Particularly, it is critical to maintain the temperature of the powder bed between strict limits, which is required to cause the powder bed to sinter so that it isn’t disturbed by powder charging. This unreliability means that eBeam PBF has typically been considered less favourable than laser-based PBF.”
Wayland Additive have developed NeuBeam providing an entirely new PBF process that is truly ground-breaking in nature and which offers the best of both laser and eBeam PBF without the compromises to open up greater potential for more industrial applications.
The new NeuBeam process is an eBeam PBF process that effectively neutralises the charge accumulation generated by the electron beam. Richardson continues, “This offers greater flexibility than laser PBF while overcoming the stability issues of eBeam PBF. What is more, both of these things mean that the NeuBeam process enables metallurgical requirements to be tailored to application requirements rather to maintain the print process within the narrow bounds permitted by the process. These process capabilities, along with the greatly improved ease of process development, also opens up the use of a much wider range of metal materials.”
Despite a couple of commonalities between EBM and NeuBeam (they are both PBF processes and they use an electron beam as the heat source to melt the metal powder) it is important to understand that EBM and NeuBeam are fundamentally different. Richardson concludes, “Unlike the traditional eBeam PBF process, the charging issues that make EBM so unstable have been fully neutralized with NeuBeam using core physics principles developed in the demanding semi-conductor industry. Moreover, NeuBeam is a hot part process rather than a hot bed process. This efficiently creates parts that are free of residual stresses because the high temperatures are only applied to the part and not the bed, ensuring free-flowing powder post-build (no sinter cake) and stress free parts with reduced energy consumption.”
The NeuBeam process overcomes many of the limitations for manufacturing large complex metal components, namely no residual thermal stresses, no gas cross-flow, and a much simplified powder removal process than existing eBeam systems. It also offers significant advantages over other AM technologies with built-in real-time in-process monitoring, allowing for rapid material development or tuning of microstructures by adapting the solidification during manufacture. With NeuBeam the process temperature is not constrained by sintering the powder bed, allowing the process temperature to be optimized to the material microstructure and/or the application.
For more information: www.waylandadditive.com