The brazeability of a cupronickel commercial alloy (Cu10Ni) was evaluated for its use as a filler alloy for high-
temperature joining of tungsten to the reduced activation ferritic/martensitic steel EUROFER 97 (W-E) and
between tungsten base materials (W-W) for its application at the first wall and divertor of future fusion reactors.
In addition, given the importance of the residual stresses in these heterogenous joints, a study of the brazing
conditions and the impact of the selected filler has been conducted using numerical software to understand its
impact on the quality of the joint.
Two thermal cycles were evaluated (1165 ◦C and 1190◦C) and selected based on the thermal characterization
of the filler alloy. The microstructural examination revealed that, in W-E joints, nickel acts as an activator
element, reacting and forming interfacial layers at the EUROFER 97 - Cu10Ni interface. In the case of the W-W
joints, a lower level of diffusion phenomenon and metallurgical interaction between Cu10Ni and base materials
were observed. The hardness profile indicated that the hardening process of EUROFER 97 was associated with
the formation of untempered martensite. On the other hand, tungsten kept the received hardness. The me-
chanical characterization by shear test reported similar values between both types of joints carried out at 1190◦C
but different when the temperature was increased (1165 °C), associated with the brittle character of tungsten and
its lower metallurgical interaction.
The numerical analysis of the brazing process carried out with ANSYS software shows that residual stresses are
accumulated mainly at the interfaces. The information provided by the simulation shows, for a 50 μm filler
thickness, the importance of mitigating the residual stress by selecting a filler with an intermediate Coefficient of
Thermal Expansion (CTE) that alleviates mechanical stresses relative to the base materials