Fig. 36 (a) Stepped shaft geometry and the arrangement of gas nozzles. (b) Comparison of experimental and simulated temperature profiles at given positions. (c) Comparison of the predicted and measured radial displacement profiles along the length of the shaft. Source: Ref 107 More

Fig. 11 Amount of air required for various sizes of air-jet nozzles at different operating pressures More

Fig. 11 Selected electrodes and guides (nozzles) used in electroslag welding. (a) Single flux-covered tube. (b) Cluster of rods taped together. (c) Flux-covered wing nozzle. (d) Flux-covered wing or web nozzle with two tubes More

Fig. 15 Selected electrodes and guides (nozzles) used in electroslag welding. (a) Single flux-covered tube. (b) Cluster of rods taped together. (c) Flux-covered wing nozzle. (d) Flux-covered wing or web nozzle with two tubes More

Fig. 19 Metal shells featuring nozzles formed by two different methods. (a) Welded nozzle. (b) Extruded nozzle More

Fig. 11 Erosive wear performance of selected materials for sandblasting nozzles. Test parameters: jet velocity, 25 m/s; sand content, 1000 ppm; test duration, 30 min; impact angle, 45° (test 1) and 90° (test 2); pH, 7 (test 1) and 5.5 (test 2). Source: Ref 16 More

Fig. 5 Fay-seal nozzles More

Fig. 55 Air consumption of simple nozzles, based on hole diameter in pipe at 80 psi (550 kPa). SCFM, standard cubic feet per minute. Adapted from Ref 51 More

Fig. 7 Typical arrangement of nozzles. Adapted from Ref 2 More

Fig. 8 Arrangement of slot nozzles in sprayer More

Fig. 2 Different patterns provided by pressure nozzles: full cone, hollow cone, and flat. Source: Ref 2 More

Fig. 4 CHF vs. flow rate for different nozzles. Source: Ref 3 More

Fig. 9 Gas nozzle field for quench hardening of disks. (a) Photo of gas nozzle field used. (b) Diagram of distribution of nozzles. Source: Ref 13 More

Fig. 23 Cross section through recirculation inlet nozzle of reactor vessel. Shown are the nozzle, the safe-end that failed, and the thermal sleeve that created susceptibility to crevice corrosion. Dimensions given in inches More

Fig. 34 Cross section through recirculation inlet nozzle of reactor vessel. Shown are the nozzle, the safe-end that failed, and the thermal sleeve that created susceptibility to crevice corrosion. Dimensions given in inches More

Fig. 46 Accelerated aqueous chloride corrosion below inlet nozzle of crude tower overhead condenser due to droplet impingement. Note partial loss of carbon steel baffles and localized corrosion along top of admiralty metal (C44300) tubes. More

Fig. 29 Close-up of blast nozzle-to-specimen geometry. Courtesy of Protech Lab Corporation More

Fig. 11 Example of thermal barrier coating on nozzle guide vane component. Courtesy of Rolls-Royce plc More

Fig. 12 Relation of nozzle angle, angle of load face, and resulting angle of impingement in peening root serrations of compressor blades. Angle of impingement, 83° More

Fig. 3 Metal nozzle coated with alumina and zirconia More