The Doppler effect in thermal reactors

R.M. Pearce
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引用次数: 5

Abstract

Experimental and theoretical work on the Doppler effect in thermal reactors is reviewed for uranium metal, UO2, thorium metal, and ThO2. The experimental values of a, the fractional increase in resonance capture per °C, have a spread many times the quoted errors. The use of different slowing-down spectra has contributed to the discrepancies. For uranium metal, approximate corrections are made to obtain the coefficient α0 appropriate to a 1E spectrum. The spread in the corrected values α0 is smaller than that for α, but remains unsatisfactory. Other experimental difficulties arise in reactivity normalizations, in obtaining the statistical weight of samples and from spurious temperature effects. Theory and experiment agree on an increase of α0 with increasing surface-to-mass ratio and that this is caused by an increase in the contribution of lower-energy resonances to the Doppler effect. It is also in agreement with the theoretical interpretation of the radial dependence of the Doppler effect in a lump. However in the region of practical interest where the surface-to-mass ratio is small, α0 is almost constant. Experimental evidence on the temperature behaviour of α0 is unsatisfactory but indicates that α0, decreases with increasing temperature. Theory predicts that α0 will vary approximately as T−12 where T is the Kelvin temperature. In the case of non-uniform temperature distribution in a fuel element, both experimental and theoretical effort is needed.

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热反应堆中的多普勒效应
综述了热堆中金属铀、UO2、金属钍和ThO2的多普勒效应的实验和理论工作。a的实验值,即每°C共振捕获的分数增加,其范围是所引用误差的许多倍。不同慢化光谱的使用导致了这些差异。对金属铀进行近似修正,得到适合于1E谱的系数α0。修正值α0的扩散小于α,但仍不能令人满意。其他实验困难出现在反应性归一化、获得样品的统计权重和虚假的温度效应中。理论和实验一致认为α0随表面质量比的增加而增加,这是由于低能量共振对多普勒效应的贡献增加所致。它也符合理论解释的径向依赖的多普勒效应在一个肿块。然而,在实际关注的面质量比较小的区域,α0几乎是恒定的。α0的温度行为的实验证据并不令人满意,但表明α0随温度的升高而降低。理论预测α0的变化近似为T−12,其中T为开尔文温度。在燃料元件温度分布不均匀的情况下,需要进行实验和理论研究。
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