Search Results for shear strength

Fig. 46 Applied shear stress and material shear strength as a function of depth representing types of fatigue damage. (a) No damage. (b) Subsurface-origin, macropitting fatigue. (c) Micropitting or surface-origin macropitting fatigue. (d) Subcase fatigue. More

Fig. 55 Applied shear stress and material shear strength as a function of depth representing types of fatigue damage. (a) No damage . (b) Subsurface-origin, macropitting fatigue . (c) Micropitting or surface-origin macropitting fatigue . (d) Subcase fatigue More

Fig. 8 Applied shear stress and material shear strength as a function of depth representing types of fatigue damage. (a) No damage. (b) Subsurface-origin, macropitting fatigue. (c) Micropitting or surface-origin macropitting fatigue. (d) Subcase fatigue More

Fig. 14 Relationship of shear strength to tensile strength More

Fig. 19 Relationship between direct shear strength and tensile strength for various gray irons, as determined by different investigators. Courtesy of American Foundry Society. Source: Ref 3 , 22 More

Fig. 2 Bond shear strength versus surface exposure/reduction in cold roll bonding. Source: Ref 2 , 3 More

Fig. 11 Calculated and experimental weld shear strength as a function of reduction in roll bonding of (a) aluminum-aluminum with one-sided, electroless nickel plating and (b) aluminum-mild steel with electroless nickel plating on steel. Source: Ref 9 More

Fig. 11 Effect of travel speed on shear strength. (a) SPCC-A1050. (b) SPCC-A5052 More

Fig. 9 Tensile shear strength of weld spots made at various energy levels showing weld strength increasing as the weld progresses, then leveling off at a strength level that gives a nugget when tensile tested to failure More

Fig. 18 Formation of low-shear-strength layers at the asperity interface More

Fig. 20 Ultimate shear strength versus temperature for polyamide (nylon) resin and resin-matrix composites More

Fig. 26 Ultimate shear strength versus temperature for polysulfone resin and resin-matrix composites More

Fig. 37 Ultimate shear strength versus temperature for thermoset polyester-matrix composites More

Fig. 49 Ultimate shear strength versus temperature for thermoset phenolic resin-matrix composites with carbon fabric reinforcements More

Fig. 13 Example of tool for shear-strength testing of plastics More

Fig. 5 Plot of tensile shear strength versus weld nugget diameter as a function of sheet thickness, t , for 1008 low-carbon steel More

Fig. 7 Effect of active metal content on shear strength, interfacial reaction layer thickness, and wetting angle when silicon nitride is brazed with copper-titanium filler metals. Open data points measured at 1100 °C (2010 °F), 1800 s; solid data points measured at 1020 °C (1870 °F), 1800 s More

Fig. 6 Shear strength of copper/56Sn-44Pb/copper solder joints as a function of joint thickness. Source: Ref 12 More

Fig. 49 Miller-Peaslee specimens for testing shear strength of single-lap brazed joints. Source: Ref 44 More

Fig. 50 Specimens (a) and a jig (b) for express shear strength testing of brazed joints. Source: Ref 47 More