Tensile stress/strain curve for

Fig. 4. Tensile stress—strain curves for polysulfone showing yield behavior at A, 20°C B, 99°C and C, 149°C. To convert MPa to psi, multiply by 145.

Fig. 3. Tensile stress—strain curve for (-) reinforced ceramic and ( " ) fiber-reinforced ceramic composite. A represents the point where the matrix...

Figure 10.6. Effect of temperature on the tensile stress-strain curve for polyethylene. (Low-density polymer -0.92g/cm . MFI = 2.) Rate of extension 190% per minute ...

Fig. 2-7 (a) Generalized tensile stress-strain curve for plastics and (b) example of a commodity plastic s stress-strain diagram. 

Fig. 4-2(1) Example of a tensile stress-strain curve for mild steel pipe material.

Fig.69 Tensile stress-strain curves for BPA-PC at various pressures (From [54])...

Figure 6.1. Stress-strain curve for aorta. Tensile stress-strain curve for human thoracic aorta in the circumferential direction obtained at a strain rate of 50% per minute. At strains less than 0.2, the elastic fibers dominate the behavior, whereas above 0.2, alignment of collagen fibers occurs. (Adapted from Silver, 1987.)...

FIG. 13.60 Generalised tensile stress-strain curves for brittle and ductile plastics efib, y and W = strain at brittle fracture, at yield and at ductile fracture, respectively b, and fffd = ultimate strength at brittle fracture and ductile fracture, respectively yield strength ( ) fracture points ( ) yield point. 

FIG. 13.61 Tensile stress-strain curves for several types of polymeric materials (Winding and Hiatt, 1961). 

Fig. 8.8 Tensile stress-strain curves for three specimens of [0,(0,90)2]SiCVLAS-IH glass-ceramic composite tested at 1000°C in air and in argon.25...

Figure 14.10 Tensile stress-strain curves for polycarbonate as a function of tem-...

Figure 14.11 Tensile stress-strain curves for polycarbonate as a function of strain at 25°C. The yield stress, Oy (maximum in the curve vs. e ), increases with increasing strain rate. (From Ref. 14.)...

F)g. 4. Tensile stress-strain curves for SAN containing 0—43 voL% glass beads after Lavengood etal. (27)... 

Figure 3.9 Tensile stress-strain curves for LLDPE, LDPE, and LDPE-EP blends.

Fig. 22.12 Tensile stress-strain curves for the four adhesives at two different strain rates, (a) Crosshead velocity 5 mm min corresponding to an initial strain rate of 0.005 s". (b) Crosshead velocity 5 mm min" corresponding to an initial strain rate of 0.5 s". ...

The tensile stress-strain curves, for the four microstructural types, cover the range from elastomers to typical semi-crystalline thermoplastics (Fig. 3.23). The lowest crystallinity material is a competitor with thermoplastic elastomers . 

Figure 3.23 Tensile stress-strain curves for the four types of EP copolymers, labelled with the per cent octene, at 21 °C strain rate 100% min (redrawn from Chum, S. et a/., ANTEC, 1775, 2003). Society of Plastics Engineers Inc.

Figure 4.16 Tensile stress-strain curves for styrene butadiene styrene tri-block copralymers (Huy, T. A et al., Polymer, 44, 1237, 2003) Elsevier.

Figure 2.2 Tensile stress-strain curves for different fiber/epoxy and aluminum and steel materials...

FIGURE 10.46 Tensile stress-strain curves for 1, Fiber B (Akzo phosphoric acid process) 2, Cordenka EHM 3, Cordenka 700 4, Cordenka 660 and 5, Enka Viscose. The solid dots indicate the stress related to the reduced cross section at fracture. The hyperbola-shaped failure envelope is represented by the dashed line. (From Northolt, M.G., Boerstoel, H., Maatman, H., Huisman, R., Veurink, J., and Elzerman, H., Polymer, 42, 8249, 2001. Reprinted with permission of Elsevier B. V.)... 

Figure 1.2 Typical schematic tensile stress-strain curves for polymers (a) brittle, amorphous thermoplastic, (b) same polymer with toughening additive, (c) intrinsically tough, semi-crystalline thermoplastic. The curves should be taken only to convey trends and not relative breaking stresses, which vary with the precise materials...

FIGURE 8. Typical room-temperature tensile stress-strain curves for the inside-debonding N22 and N24-A CMC systems, and the outside-debonding N24-B CMC system (total fiber content -40 vol.%). 

FIGURE 2. Room temperature tensile stress-strain curves for 1-D and 2-D SiC/RBSN composites containing -24 vol% fibers, and unreinforced RBSN [8, 9]... 

Tensile stress-strain curves for 2-D Hi-Nicalon /Al203 composites are shown in Fig. 17. Tensile test fracture surfaces for these composites were similar to that... 

FIGURE 24. Room temperature tensile stress-strain curves for various CMCs fabricated via directed metal oxidation. 

FIGURE 5. Tensile Stress-Strain Curves for As-Prepared and Post 600°C-1000 Hr. Oxidation SiOC-Nextel 312 BN 2-D Composites... 

Figure 10.1. Tensile stress-strain curves for four natural rubber compounds of different hardnesses 73 IRHD contains 50 parts of a reinforcing black, and different vulcanizing systems account for the different curves of the two gum compounds (47 and 33 IRHD). (Lindley, 1964.)...

Fig. 2. Tensile stress-strain curves for N720/A ceramic composite at various temperatures. Results at 23, 1200 and 1330 °C from Ruggles-Wreim et al ...

Retained strength and modulus of the specimens that achieved a run-out are summarized in Table III. Tensile stress-strain curves obtained for the specimens subjected to prior creep ate presented in Fig. 8 together with the tensile stress-strain curves for the as-processed material. Results from prior work obtained at 1200 °C are included in Table III and in Fig. 8 for comparison. Prior creep in air at 1000 and 1100 °C had little effect on tensile strength. However, a reduction in modulus was observed. The modulus loss was 14% for the specimen pre-crept in rur at 1000 °C and 16% for the specimen pre-... 

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