Search Results for transition temperature

Fig. 5-9 The transition temperature as a function of tempering temperature, derived from the curves in Fig. 5-8 More

Fig. 5-63 The effect of aging temperature and time on the transition temperature of a 3140 steel, from data such as in Fig. 5-62 . (From L.D. Jaffee and D.C. Buffum, Trans. ASM , Vol 42, p 604 (1959), Ref 31 ) More

Fig. 5-64 The effect of aging temperature and time on the transition temperature of a 3140 steel, obtained from the data in Fig. 5-63 . (From L.D. Jaffee and D.C. Buffum, Trans. ASM , Vol 42, p 604 (1959), Ref 31 ) More

Fig. 16 Relationships among glass transition temperature ( T g ), melt temperature ( T m ), molecular weight, and polymer properties. Source: Ref 13 More

Fig. 15.2 Effect of moisture on glass transition temperature More

Fig. 5-67 Effect of aging time on the transition temperature and on the concentration of P on the prior austenite grain boundaries as revealed by Auger analysis of the fracture surface of the impact samples (From Z. Qu and K.H. Kuo, Met. Trans ., Vol 6A, p 1333 (1981), Ref 33 ) More

Fig. 8-22 Effect of primary ferrite grain size on the impact transition temperature of two steels. ((a) from same source as Fig. 8-21a . (b) from same source as Fig. 8-21b )) More

Fig. 6.28. Relationship between changes in ductile-to-brittle transition temperature obtained from small punch tests and Charpy tests for Cr-Mo-V steels ( Ref 63 ). More

Fig. 23 Effect of stress state on the ductile-to-brittle transition temperature, T DB , for polycarbonate. P , pressure; σ, stress. (a) Tensile test. (b) Puncture test. (c) Strip biaxial test. (d) Notched beam test More

Fig. 17 Variation of glass transition temperature ( T g ) with cure time and temperature. Source: Ref 23 More

Fig. 8 Effect of binary alloy additions on the transition temperature of niobium. Source: Ref 5 More

Fig. 4.26 Characteristics of the transition-temperature range for Charpy V-notch testing of semikilled low-carbon steel plate (0.18% C, 0.5% Mn, 0.07% Si), as determined by (a) fracture energy, (b) fracture appearance, and (c) fracture ductility. The drawing at lower right in each graph More

Fig. 4.29 Hypothetical transition-temperature curves for two steels, showing that room-temperature results can be fallible More

Fig. 4.36 Effect of yield strength on shift in transition temperature between impact and static plane-strain fracture toughness curves. Source: Ref 4.36 More

Fig. 12 Increase in transition temperature with α′ formation with aging for (a) annealed 2705 and (b) cold-worked 2205. Source: Ref 4 More

Fig. 11 Charpy V-notch impact ductile to brittle transition temperature (DBTT) of titanium-stabilized 29%Cr plus 4%Mo alloys test. Source: Ref 11 More

Fig. 12 Charpy V-notch impact ductile to brittle transition temperature (DBTT) of niobium-stabilized 29%Cr plus 4%Mo alloys test. Source: Ref 11 More

Fig. 14 Change in transition temperature with thickness for 29Cr-4Mo-2Ni alloy. Source: Ref 12 More

Fig. 35 Shift in ductile-brittle transition temperature curve to a higher temperature for AISI 3140 steel by holding at 500 °C and continuous cooling through the temper embrittlement critical range. Source: Ref 35 More

Fig. 15.28 Effect of steel carbon content on the transition temperature between upper and lower bainite. Source: Ref 15.22 as published in Ref 15.19 More