<p>Tungsten remains a material of considerable interest to engineers for nuclear fusion reactor designs, for the plasma-facing components (PFCs) thanks to its outstanding thermal conductivity and unmatched high melting point. However, tungsten remains a difficult to additively manufacture metal, due to its highly brittle nature, leading to cracking during cooling. In situ alloyed 90 wt% W–10 wt% Ta powder was processed by laser-based powder bed fusion (LPBF), with Ta added to reduce cracking during solidification. However, it becomes of interest to understand any compositional gradients which may occur during in-situ alloying. An 85&#xa0;mm tall cylinder was manufactured via LPBF and was sectioned and analysed for chemical composition variation along the height. Whilst a discrete element modelling (DEM) framework was developed to simulate the powder behaviour during the tipping / pouring and the LPBF spreading motion. Both model prediction and experimental measurement agreed that the W powder segregates in higher concentrations toward the top of the build, whilst the Ta powder segregates to higher concentrations toward the bottom of the build. Experimental measurements suggest a +/− 1% variation from the nominal composition, whilst DEM predictions were a little wider, at +/− 2%. It is noted that a compositional gradient in the build may limit the end-application of LPBF built components due to issues with in-service performance thermally and mechanically, however this would need to be assessed on a case-by-case basis, as blends with smaller compositional gradient or different alloying elements may have varying effects upon performance.</p>

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Chemical composition gradients within an In-situ alloyed tungsten-tantalum laser powder-bed fusion: modelling and validation

  • Richard Turner,
  • Ahmet Guner,
  • Abd El-Moez A. Mohamed,
  • Dina M. Fouad,
  • Moataz M. Attallah

摘要

Tungsten remains a material of considerable interest to engineers for nuclear fusion reactor designs, for the plasma-facing components (PFCs) thanks to its outstanding thermal conductivity and unmatched high melting point. However, tungsten remains a difficult to additively manufacture metal, due to its highly brittle nature, leading to cracking during cooling. In situ alloyed 90 wt% W–10 wt% Ta powder was processed by laser-based powder bed fusion (LPBF), with Ta added to reduce cracking during solidification. However, it becomes of interest to understand any compositional gradients which may occur during in-situ alloying. An 85 mm tall cylinder was manufactured via LPBF and was sectioned and analysed for chemical composition variation along the height. Whilst a discrete element modelling (DEM) framework was developed to simulate the powder behaviour during the tipping / pouring and the LPBF spreading motion. Both model prediction and experimental measurement agreed that the W powder segregates in higher concentrations toward the top of the build, whilst the Ta powder segregates to higher concentrations toward the bottom of the build. Experimental measurements suggest a +/− 1% variation from the nominal composition, whilst DEM predictions were a little wider, at +/− 2%. It is noted that a compositional gradient in the build may limit the end-application of LPBF built components due to issues with in-service performance thermally and mechanically, however this would need to be assessed on a case-by-case basis, as blends with smaller compositional gradient or different alloying elements may have varying effects upon performance.