Search Results for sheets

Fig. 16 Examples of ductile fracture on shear planes. (a) Void sheets from propagation of a crack between widely spaced inclusions within a shear band in a 4340 steel. Stress axis is vertical. Source: Ref 41 . (b) Ductile crack growth in HSLA steel (A710). Source: Ref 77 More

Fig. 26 Effect of particles on fracture toughness. (a) Void sheets linking three inclusions in a sectioned tensile sample of 4340 steel. (b) Schematic relationship between crack tip opening displacement and inclusion spacing. Source: Ref 42 . (c) K Ic for a martensitic 0.45C-Ni-Cr-Mo-V More

Fig. 8 Large voids in AISI 4340 linked by narrow void sheets consisting of small microvoids. (a) Section through the necked region of a 4340 steel specimen showing the formation of a voids sheet between two voids formed at larger inclusions. (b) Schematic of nucleation at smaller particles More

Fig. 15 Redrawing characteristics of 1.0 mm (0.040 in.) thick sheets of several copper alloys. Curves of lower slope indicate a lower rate of work hardening and therefore a higher capacity for redrawing. Source: Ref 3 More

Fig. 17 Elongation versus grain size for alloy C26000 sheets of various thicknesses. Source: Ref 3 More

Fig. 8 Magnetic pulse welding of flat sheets. Source: Ref 34 More

Fig. 16 Operations required for joining two sheets of superplastic alloy using the superplastic forming/diffusion bonding process More

Fig. 17 Operations required for joining three sheets of superplastic alloy using the superplastic forming/diffusion bonding process More

Fig. 14 Parameters in a large strain dislocation structure containing sheets of extended lamellar boundaries (LBs) with stippled low-angle (bamboo) incidental dislocation boundaries (IDBs) bridging between them. High-angle LBs are represented by heavy line weight and medium-angle LBs by medium More

Fig. 6 Microstructure of thin-gage sheets. (a) Roll-compacted CP titanium. (b) Roll-compacted Ti-6Al-4V. Copyright 2005 by The Minerals, Metals & Materials Society. Reprinted with permission. Source: Ref 20 More

Fig. 1 Cross-sectional sketch of resistance spot welding of two sheets More

Fig. 11 Direct cast sheets of IC-50 (Ni-23.5Al-0.5Zr-0.08B, at.%) and IC-218 (Ni-16.7Al-8.0Cr-0.4Zr-0.08B, at.%) Ni 3 Al alloys. Source: Ref 84 More

Fig. 16 Examples of ductile fracture on shear planes. (a) Void sheets from propagation of a crack between widely spaced inclusions within a shear band in a 4340 alloy steel (stress axis is vertical). Source: Ref 41 . (b) Ductile crack growth in high-strength, low-alloy steel (A710). Source More

Fig. 54 Operations required for joining two sheets of superplastic alloy using the SPF/DB process More

Fig. 55 Operations required for joining three sheets of superplastic alloy using the SPF/DB process More

Fig. 56 Example of a four-sheet SPF/DB process in which the outer sheets are formed first and the center sheets are then formed and bonded to the outer two sheets. More

Fig. 5 Two types of shearing lines for cutting coiled strip into flat sheets More

Fig. 6 Relation of weld nuggets to embossed regions of metal sheets used in projection welding. (a) Electrical circuit loop is completed when current travels through embossed projection contact points. (b) Addition of pressure after welding current is turned off causes plastic deformation More

Fig. 2 Placement of welds to join two sheets of metal in a T-joint. (a) Configuration not recommended due to unbalanced shrinkage forces. (b) Preferred setup that results in balanced forces and minimum distortion More

Fig. 3 Placement of welds to join three sheets of metal in a T-joint. (a) Configuration that can be used to join three stock thicknesses. (b) Recommended configuration incorporating scalloped edges to permit alternate welding of spots in two thicknesses only More