Search Results for compressing testing

Fig. 16.22 Twist compression test (TCT). (a) Schematic of the test. (b) Sample output of lubricant evaluation using TCT. COF, coefficient of friction. Source: Ref 16.65 More

Fig. 1 Gleeble test unit used for hot-tension and hot-compression testing. (a) Specimen in grips showing attached thermocouple wires and linear variable differential transformer (LVDT) for measuring strain. (b) Close-up of a test specimen. Courtesy of Duffers Scientific, Inc. More

Fig. 8.10 NASA short-beam compression test fixture. Source: Ref 8.50 More

Fig. 5.9 Deformation behavior of the magnesium alloy MgAl6Zn in hot-compression tests in the temperature range between 200 and 220 °C (Source: Schmidt/Beck) More

Fig. 13.4 Modified ASTM D 695 compression test More

Fig. 13.5 IITRI compression test More

Fig. 13.11 Typical notched tension/compression test More

Fig. 19.6 Compression tests on repaired and unrepaired delaminated fastener holes More

Fig. 8 Compression test of two steel cubes deep case hardened only on the top and bottom surfaces. A compressive force perpendicular to the case-hardened surfaces caused cracking (arrows) in the very hard (66 HRC) cases on both surfaces. The soft, ductile cores simply bulged under More

Fig. 12.19 Barreling during compression test More

Figure 12.38 Fixture for static and fatigue compression testing at cryogenic temperatures. 1) split aluminum compression blocks, 2) stainless steel yokes, 3) aluminum alignment sleeve, 4) titanium rods, 5) lock collar. More

Figure 12.39 Specimen configuration used for compression testing of laminates at cryogenic temperature; (a) square specimen; (b) round specimen. More

Fig. 5.5 Schematic of Mohr’s circle in uniaxial tensile and compression tests ( Ref 5.1 ) More

Fig. 7.7 Schematic of the twist compression test. T , applied torque; r , mean radius of the tool. Source: Ref 7.17 More

Fig. 9.2 Compressive testing relies on loading to induce fracture. Shown here are the simple right-circular cylinder geometry and the less frequently used catenary cylinder geometry. The compressive strength is determined by the fracture load divided by the cross-sectional area. More

Fig. 18.1 Correction of flow stress data obtained from a compression test [ Altan et al., 2001 ] More

Fig. 19 Barreling during compression test. Source: Ref 2 More

Fig. 4.4 Compression test specimen. (a) View of specimen, showing lubricated shallow grooves on the ends. (b) Shape of the specimen before and after the test More

Fig. 4.5 Compression test tooling. [ Dixit et al., 2002 ] More

Fig. 4.14 Lead samples on the compression test die. [ Dixit et al., 2002 ] More