The expanding copper mandrel test performed at three strain rates (3.2$ imes$10E -5/s, 2.0$ imes$10E-6/s and 1.2$ imes$10E-7/s) over 553-873 K temperature range by varying the heating rates (8-1$0^{circ}C$/s, 1-2$^{circ}C$/s and 0.5$^{circ}C$/s) in air and in vacuum (5$ imes$10E-5 torr). The yield stress peak, the strain rate sensitivity minimum and the activation volume peaks could be explained in terms of the dynamic strain aging. The activation energy for dynamic strain aging obtained from the yield stress peak temperature and strain rate was 196 KJ/mol and this value was in good agreement with the activation energy for oxygen diffusion in $alpha$-zirconium and Zircaloy-2 (207-220 KJ/mol). Therefore, oxygen atoms are responsible for the dynamic strain aging which appeared between 573 K and 673 K. The yield stress increase due to the oxidation was obtained by comparing the yield stress in air with that in vacuum and represented by the percentage increase of yield stress ( $sigma$$^{a}$ $_{y}$ - $sigma$$^{v}$ $_{y}$ / $sigma$$^{v}$ $_{y}$ ). The slower the strain rate, the greater the percentage increase occurs. In order to estimate the yield stress of PWR fuel cladding material under the service environment, the yield stress in water was obtained by comparing the oxidation rate in air that in water assuming the relationship between the oxygen pick-up amount and the yield stress increase.