5.2. Mechanical Properties at Low Temperature
5.2.1 Tensile Properties
5.3. Mechanical Properties at Elevated Temperature
5.3.1 Short-time Tensile Properties - Impact Properties
5.4.1 Fatigue Strength at Room Temperature
Mechanical Properties (Section 5)
(1) Strauss J. Metals and Alloys for Industrial Applications Requiring Extreme Stability. Trans. ASST, Vol. 16, (1929), pp. 191-226.
(2) Weldon B.A., Towers, J.A. and Patton, A.M. Nickel Silver as an Engineering Material. Metals & Materials, Vol. 4 (1970), pp. 299-303.
(3) Isler, P. and Form, W. The Mechanism of Fire-Cracking. J. Inst. Metals, Vol. 100 (1972), pp. 107-113.
(4) Kirchberg, K. Richtungsabhangigheit der mechanischen Eigenschaften von Federwerkstoffen. Neue Hutte. Vol. 11, (1966), pp. 160-162.
(5) France, W.D. and Trout, D.E. Selecting Copper Alloys for Fatigue Applications. Metal Progress, Vol. 101 (1972), No. 6, pp. 69, 71-72.
(6) Anderson, A.R., Swan, E.F. and Palmer, E.W. Fatigue Tests on Some Additional Copper Alloys. Proc. ASTM, Vol. 46 (1946), pp. 678-692.
(7) McAdam, D.J., Jr. Fatigue and Corrosion-Fatigue of Spring Material. Trans. ASME, No. 51, (1929), pp. 45-58.
