In all the investigations of corrosion and leaching of radioactive waste containers for final storage in rock salt, the assumption was made of direct intrusion of brine to the waste container or to the waste matrix. Previous studies that assume waste containers are free-standing in brine (and a self-consuming brine) do not adequately describe the actually occurring conditions and sequences for the case of heat- producing waste. The occurring processes, like crystallization, resolving, evaporation, and condensation, will lead to a possible build-up of a protective layer around the waste container, or to cavity formation in the vicinity of the heat generating source. Previous considerations of long-term safety of final repositories with heat-producing waste in a salt dome incorrectly assumed the rock salt fill material will stay homogenous, and do not take into account a change in the fill properties (especially porosity and permeability) caused by a brine intrusion and the resulting salt resolution and crystallization. Investigations of possible sub-processes occurring under final repository conditions in rock salt on a small-area, short-period scale (including modelling) were prepared. Various laboratory experiments, under normal pressure as well as under increased pressure conditions, and with different temperature gradients and moisture content, were carried out to analyse the behaviour of the system, to identify the main processes and to determine the essential influencing factors. The experiments show compacted continuous zones (the initial porosity will be reduced from approximately 35% to approx. 15-20% or even less) and loosened areas (porosity increasing 50 to 100%). Local densities of up to ρ = 2.04 g/cm{sup}3, with a porosity of 8%, were found. Temperature gradients can initiate convection processes, especially in the non-compacted areas, which in turn will result in further resolving and dissolving of salt. In completely brine-saturated porous-salt, the growth of salt crystals takes place along the temperature gradient, which creates salt deposits in colder zones and large brine filled cavities in warmer regions. Transferring the observed phenomena to repository conditions, it can be postulated: 1. In case of a brine-filled repository section, the salt transports toward the colder section, and in addition, gravity could allow the container to sink downwards into the rock salt. This effect, under certain circumstances, could result in serious safety issues. 2. The compaction of salt in the colder repository section (roof) might prevent further brine inflow into the repository section after some time has elapsed. 3. All processes are dependent on the rate of brine-inflow and the content of gaseous and liquid phases in the disposal gallery.
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机译:在岩盐中最终储存的放射性废物容器的腐蚀和浸出的所有研究中,假设是直接侵入盐水到废物容器或废基质。以前的研究,假设废物容器在盐水中独立(和自耗盐水),不能充分描述用于热产生废物的实际发生的条件和序列。如结晶,分辨,蒸发和冷凝,如结晶,分辨,蒸发和冷凝的发生方法将导致在废物容器周围的保护层的可能积聚,或者在发热源附近的空腔形成。之前对盐圆顶中的热量产生的最终存储库的长期安全性的考虑因素不正确地假设岩盐填充材料将保持均匀,并且不考虑由此引起的填充性能(特别是孔隙度和渗透率)的变化盐水侵入和所得盐分分辨率和结晶。制备在小面积的岩盐中的最终储存条件下发生可能的子进程的调查,短暂的短周期秤(包括建模)。进行各种实验室实验,在正常压力和增加的压力条件下进行,并进行不同的温度梯度和水分含量,以分析系统的行为,以确定主要过程并确定必要的影响因素。实验显示压实的连续区域(初始孔隙率将从约35%降低至约。15-20%甚至更低)和松散区域(孔隙率增加50至100%)。发现,发现孔隙率为8%的ρ= 2.04g / cm {sup} 3的局部密度。温度梯度可以启动对流过程,尤其是在非压实区域中,这反过来会导致进一步解决和溶解盐。在完全盐水饱和的多孔盐中,盐晶的生长沿温度梯度进行,其在较冷的区域和大盐水填充空腔中产生盐沉积物。将观察到的现象转移到储存条件下,它可以假设:1。如果填充盐水填充的储存部分,盐向较冷的部分运输,此外,重力可以让容器向下沉入岩盐中。在某些情况下,这种效果可能会导致严重的安全问题。 2.在一段时间后,较冷的储存库部分(屋顶)中盐的压实可能会阻止进一步进入储存库部分的盐水流入。所有方法依赖于盐水流入的速率和处理库中气态和液相阶段的含量。
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