Fig. 8 Camera for Berg-Barrett topography. Sample is mounted on a tilting stage (right), and the film plate is held close to the sample surface by a supporting plate that also screens the film plate from scattered incident radiation. Source: Ref 15 More

Fig. 37 Effect of tilting on electron-diffraction pattern. Diffraction pattern (a) and indexed schematic (b) after tilting about [1 1 0] γ . The zone axes are [11 1 ] γ and [111] σ . Compare with Fig. 38 . More

Fig. 38 Effect of tilting on electron-diffraction pattern. Diffraction pattern (a) and indexed schematic (b) after further tilting about [1 1 0] γ . The zone axes are [11 2 ] γ and [110] σ . Compare with Fig. 37 . More

Fig. 46 Diffraction patterns obtained by tilting a single crystal about the normal to the (200) plane. Zone axes: (a) [012], (b) [011], (c) [010], (d) [023], (e) [021] More

Fig. 2 Typical lip-axis tilting crucible furnace used for fuel-fired furnace melting of copper alloys. Similar furnaces are available that tilt on a central axis More

Fig. 7 Two variations of a tilting crucible furnace. (a) Center axis. (b) Lip axis More

Fig. 2 Transfer area from a tilting aluminum furnace to a launder. Courtesy of AGN Nachrodt More

Fig. 53 (a) Change of the outer radius and tilting of the different ring types after quenching in the gas-nozzle field. (b) Tilting angle of the outer surface: comparison of experimental and numerical data. (c) Temperature distribution in the cross section of a ring at the beginning More

Fig. 2 Barrels available in a variety of sizes. (a) Standard open-end, tilting. (b) Bottlenecked. (c) Horizontal octagonal. (d) Triple-action, polygonal. (e) Multiple drums. (f) Multicompartment. (g) End loading. (h) Submerged More

Fig. 23 Diagram of martensite crystal, showing shear and surface tilting. Courtesy of M.D. Geib (adapted from Ref 34 ) More

Fig. 3 Diagram of martensite crystal, showing shear and surface tilting. Source: Ref 3 More

Fig. 13 Use of tilting to eliminate draft. The aluminum alloy sponson attachment forging was originally forged with 7° draft (a); tilting made it possible to forge the high, thin rib above the trough without applied draft. See text for details. Dimensions given in inches. More

Fig. 18 Close-tolerance longeron splice forging that substituted tilting and shift draft for applied draft (a). Tilting of the forging in the die impression is shown in (b). See Example 4. Dimensions in figure given in inches. Item Close-tolerance forging Material Aluminum alloy More

Fig. 19 Close-tolerance attachment support forging that made use of tilting of the die impression to reduce draft. Views of the forging are shown in (a) and (b); forging positions are shown in (c). See Example 5. Dimensions in figure given in inches. Item Close-tolerance forging More

Fig. 21 Close-tolerance forging for wing cap fittings that employed tilting to eliminate draft and obtain net-forged surfaces. See Example 7. Dimensions in figure given in inches. Item Close-tolerance forging Material Aluminum alloy 7075 (a) Heat treatment (temper) T6 More

Fig. 10 Close-tolerance forging that illustrates tilting of the die impression to forge ribs as oblique webs. Dimensions given in inches More

Fig. 29 Two failure cases showing the effect of misalignment or tilting moments on rolling-element bearings. (a) Deep-groove ball bearing with rotating outer ring. (b) Tapered roller bearing with rotating outer ring. Source: Ref 24 More

Fig. 61 Excessive tilting moment that overloaded a slewing ring used in a fork lift. Source: Ref 25 More

Fig. 10 Tilting rotary furnace. Source: Ref 16 . Reprinted with permission from Seco/Warwick Corp. More

Fig. 12 Tilting the mold after the pour. Courtesy of K. Whaler, Stahl Specialty Company, Kingsville, MO More