Search Results for sintered density

Fig. 1 Thermal conductivity of sintered 316L as a function of sintered density for hydrogen (left) and 30%H 2 -70%N 2 sintering atmosphere (right). Broken line represents pore-free 316L. More

Fig. 45 Effect of sintered density on corrosion resistance of sintered 316 type alloys. Source: Ref 1 , 32 More

Fig. 5 Fractional sintered density versus fractional green density for tungsten specimens. 3N tungsten powder with particle size (FSSS) of 2.2 μm More

Fig. 26 Variation of sintered density and compact properties with the degree of sintering as represented by the sintering temperature. Source: Ref 4 More

Fig. 3 Effect of sintered density on the yield and tensile strengths of press and sintered Ti-6Al-4V BE compacts. Source: Ref 22 More

Fig. 3 Young's modulus as a function of sintered density. Data from Ref 5 More

Fig. 33 Prediction of sintered density versus temperature as modeled for a boron-doped stainless steel powder compacted to an initial relative density of 0.72 and compared with experimental data. Source: Ref 153 More

Fig. 24 Effect of sintered density on electrical conductivity. Source: Ref 14 More

Fig. 3 Sintered density versus sintering temperature for tungsten specimens, 3N tungsten powder with particle sizes (FSSS) of 2.15 μm and 4.05 μm, die-pressed with compacting pressure of 300 MPa (43,500 psi). Source: Ref 7 More

Fig. 6 Fractional sintered density of W-La 2 O 3 versus the La 2 O 3 content. 3N tungsten powder with particle size (FSSS) of 2.0 μm. Source: Ref 6 More

Fig. 8 Fractional sintered density of molybdenum compacts as a function of fractional green density. The powder used was a 99.9% pure molybdenum powder with FSSS = 4.6 μm. Compaction pressures ranged from 100 to 500 MPa (14,500 to 72,500 psi). Source: Ref 4 More

Fig. 17 Comparison of CP titanium and Ti-6Al-4V alloy. (a) Sintered density vs. temperature. (b) Vickers hardness compacts sintered at different temperatures for 1 h More

Fig. 44 Relationship between sintered density and weight loss of three austenitic stainless steels in 40% HNO 3 solution. Source: Ref 31 More

Fig. 14 (a) Minimum grain size for a given final sinter density and (b) the corresponding sintering cycle for achieving this goal in a 17-4 PH stainless steel. Source: Ref 41 More

Fig. 14 (a) Minimum grain size for a given final sinter density and (b) the corresponding sintering cycle for achieving this goal in a 17-4 PH stainless steel. Source: Ref 41 More

Fig. 31 Sintered fractional density versus sintering temperature for a 30 μm Ni-Cr-Co alloy powder processed from a green density of 0.62 using a hold time of 15 min at each temperature. The dramatic change in sintered density over a narrow temperature range is characteristic of liquid-phase More

Fig. 10 Effect of density on mechanical properties of sintered iron (F-0000). (a) Tensile strength. (b) Elongation. (c) Hardness. (d) Unnotched Charpy impact energy More

Fig. 11 Effect of density on the elastic modulus of sintered irons and steels after sintering to various densities More

Fig. 4 Effect of density on the fracture toughness of press and sintered Ti-6Al-4V BE compacts. The values are not valid K Ic and thus are labeled as K Q . Source: Ref 21 More

Fig. 8 Effect of compact density on fatigue strength of CIP and sintered Ti-6Al-4V BE compacts. Note that the higher densities are only possible in the low-chloride material. BUS, broken-up structure; TCP, thermochemical processing. Source: Ref 15 More