Search Results for flow rate

Fig. 12 The effect of solution flow rate on the corrosion fatigue crack growth rate of a medium-sulfur, low-alloy steel tested in deaerated 288 °C (550 °F) water. Tests at high flow rate on the 3-side-open compact-type specimens permit the aggressive crack chemistry to be flushed out, reducing More

Fig. 1 Effect of flow rate, temperature, and oxygen on corrosion rate of steel in saltwater. Source: Ref 16 More

Fig. 14 The influence of solution flow rate on the corrosion rate (expressed as a current) showing the response in different flow regimes More

Fig. 14 Effect of abrasive flow rate and grit number on depth of cut (garnet abrasive; 220 MPa, or 32 ksi water pressure; 0.46 mm, or 0.018 in., waterjet diameter; 152 mm/min, or 6 in./min, traverse speed; cast iron). Source: Department of Industrial and Manufacturing Engineering, University More

Fig. 3 Effect of powder flow rate on material removal. Workpiece material: plate glass More

Fig. 7 Pressure versus flow rate with various WJM nozzle sizes More

Fig. 12 Effect of flow rate of quenching oil on the cooling time of scale-free steel bars. Temperature range criteria are shown in Table 1 . Source: Ref 9 More

Fig. 19 Impeller type indicating relative power apportioned to flow rate ( Q ) and velocity head (H). Source: Ref 19 More

Fig. 11 Effect of metal flow rate on size of water-atomized Fe-15wt%Si powder. Source: Ref 15 More

Fig. 19 Relationship between apparent density and flow rate. Source: Ref 13 More

Fig. 20 Effect of nitrogen flow rate during purging on the residual gas pressure remaining in an aluminum bronze melt. The curve for oxygen purging is also shown. Source: Ref 16 , 18 More

Fig. 19 Plot of flow rate versus time showing the behavior of a ceramic filter during the course of pouring until complete blockage occurs More

Fig. 17 Effect of nitrogen flow rate during purging on the residual gas pressure remaining in an aluminum bronze melt. The cure for oxygen purging is also shown. Source: Ref 19 , 21 More

Fig. 2 Tolerance to variation in welding current and plasma gas flow rate in pulsed- and continuous-current keyhole welding; boundaries show the welding parameter combinations at which specific defects are likely to occur. Welding parameters: nozzle bore, 2.36 mm (0.0929 in.); electrode More

Fig. 11 Plastic flow rate R x (μm/pass) to the sliding direction X , and R y (μm/pass) to the direction normal to sliding direction Y , at the indentation mark on S45C flat surface in relation to contact pressure ( P m ). Boundary oil lubrication. Source: Ref 25 More

Fig. 2 Tolerance to variation in welding current and plasma gas flow rate in pulsed and continuous current keyhole welding; boundaries show the welding parameter combinations at which specific defects are likely to occur. Welding parameters; nozzle bore, 2.36 mm (0.0929 in.); electrode More

Fig. 6 Flame conditions obtained as oxygen flow rate increases from zero to an excess of oxygen in an oxyacetylene welding torch More

Fig. 14 Effect of quenchant flow rate on the cooling characteristics of (a) reference oil, (b) 20% polyalkylen glycol polymer quenchant, and (c) water at 40 °C (105 °F). Source: Ref 37 More

Fig. 13 Effect of power and powder mass flow rate on deposition width and height for a laser-based directed-energy deposition process for Ti-6Al-4V alloy. Source: Ref 6 More

Fig. 11 Summarizes the effect of powder flow rate and layer thickness on hardness of DED fabricated H13 steel More