Spark Sintering of TiB₂ Reinforced Fe Matrix Composites with Both High Thermal Conductivity and Hardness, and Their Microstructural Characterizations

抄録

TiB₂ reinforced Fe matrix composites were investigated for their potential as a new generation of hot work tools which are mainly characterized by high thermal conductivity and high hardness in comparison with conventional materials. In this work, Fe–30 vol%TiB₂ composites were sintered at 1373 K for different holding times (0, 0.3, 0.6, 1.8 and 3.6 ks). Apart from Fe and TiB₂, newly formed phases of Fe₂B and TiC were found in all sintered compacts. A good Fe/TiB₂ interfacial cohesion was confirmed at atomic level at 0 ks, which was due to the occurrence of the special orientation relationship between {110} planes of Fe and {1010} planes of TiB₂. The observation of dislocations in TiB₂ particles, attributed to the activation of slip systems, showed the plastic deformation ability of TiB₂ at high temperature. The reaction between Fe and TiB₂ was due to TiB₂ dissolution in Fe at 1373 K and different diffusion depth of B and Ti atoms in Fe. Consequently, B directly reacted with Fe, since the solubility of B atoms was low in both α-Fe and γ-Fe. TiC probably precipitated from Fe–Ti–C solid solution along Fe grain boundaries in the cooling stage after sparking sintering, leading to a layer of Fe wrapping around TiB₂. Among all the compacts, the one sintered at 1373 K for 0.6 ks displayed the excellent properties which were comparable in Vickers hardness and 133% higher in thermal conductivity, compared with that of SKD61 as the commonly used practical material. This work provides a new perspective to fabricate a future generation of hot work tools.

Fig. 5 HAADF images of Fe–30 vol%TiB₂ compacts sintered at (a) 1373 K for 0 ks and (b) the high magnification image corresponding to the area in (a) marked by dashed box; (c), (d), (e) and (f) placed on the right are mapping analysis images of Fe, Ti, B and C corresponding to (a).