硼硅酸盐玻璃固化体中ZnO对模拟高放废液Mo浸出率的影响及其模型预测

对于高钼核废料玻璃固化体而言,Mo浸出率是关键产品性能之一。在某高MoO_(3)(质量分数约为3%)模拟高放废液硼硅酸盐固化玻璃配方研究中,设计了ZnO含量的系列变化,进行了Mo浸出率的测试,依据实验数据建立了Mo浸出率的数理统计结构预测模型并进行了模型验证。结果显示,在研究配方范围内,Mo的浸出主要受约530 cm^(-1)处Si-O-Si摇摆振动及约1180 cm^(-1)处Q4基团中Si-O-Si弯曲振动的影响,且B_(2)O_(3)、Zr O_(2)及碱金属皆会影响这两个结构单元的相对浓度,进而影响Mo的浸出。在这种复杂玻璃系统中,ZnO含量的质量分数高于3.5%后Mo浸出率有一定程度增长。模型结果表明:建立的Mo浸出率结构模型具有较好的模拟精度及统计可靠性,模型迭代后的精度及可靠性皆获得了进一步提升,可用于设计成分范围内玻璃配方筛选中对Mo浸出率的迅速预判。

膨润土颗粒充填施工接缝的缓冲层膨胀力研究

在高放废物处置库中,缓冲层通常以高压实膨润土砌块拼接回填形成,这势必在金属罐、砌块、围岩之间留下不可忽略的施工接缝.通过在位于试验舱底的压实膨润土上部预留接缝,开展接缝充填膨润土颗粒工况下的试样膨胀力测试,以掌握膨润土颗粒充填施工接缝对缓冲层膨胀力特性的影响.研究结果表明:试样水化方向不同,膨胀力发展过程存在较大差异,但膨胀稳定时间差别不大;从接缝端入渗时,试样均表现出随注水时间增长,膨胀力逐步提升,直至稳定在最高膨胀力;随着接缝宽度增大,最终膨胀力出现显著降低,且膨胀稳定时间显著增加;在施工接缝中充填膨润土颗粒可显著提升缓冲层最终膨胀力,保证其“自密封”要求.

HLW竖直处置热分析

处置库中废物罐表面的最高温度不能超过100℃,这个标准决定着处置库的热库容。废物罐处置时剩余衰变热量、工程屏障系统材料的热特性、间隙的存在、处置主岩的初始温度及其热特性、处置库的布局等都是影响处置库中废物罐表面温度的因素。文章对处置主岩和工程屏障系统材料的热物理特性进行了分析和研究,对工程屏障系统不同间隙的热传导特性进行了研究,应用解析法和数值法对单个废物罐周边的温度发展进行了热传导特性研究。研究表明,最重要和最敏感的参数是废物罐的初始处置剩余衰变热量;而主岩和工程屏障系统材料参数的不确定性及其自然变化性和工程屏障系统废物罐周边间隙是影响废物罐表面最高温度的两个最主要的因素;工程屏障系统内部间隙的温度偏差小于10℃,内部间隙越大,温度偏差越大,外部间隙在被水充填时的温度偏差比间隙被空气充填时的温度偏差要小1～3℃。

铁磷模拟HLW熔体的腐蚀性能

在铁磷模拟ＨＬＷ熔体和硼硅酸盐熔体ＤＷＰＦ内测量了六种耐火材料的动态腐蚀速度，测量在 １０００～１３００℃之间进行，在铁磷熔体中，致密氧化铝和氧化铬耐火材料有最低的熔线腐蚀速度，二氧化硅、锆英石和ＡＺＳ耐火材料的腐蚀速度比较高．同时，氧化铝和氧化铬耐火材料在铁磷熔体中的腐蚀速度小于它们在硼硅酸盐熔体ＤＷＰＦ中的腐蚀速度．对氧化铬耐火材料来说，其在三种含有模拟ＨＬＷ废料的铁磷熔体中的熔线腐蚀速度＜０．１ｍｍ／ｄａｙ．可以认为商品制造的致密氧化铝和氧化铬耐火材料是可以用来熔化很多铁磷ＨＬＷ废料的，甚至可以熔化含有１６ｗｔ％氧化钠的ＨＬＷ废料．

Effect of drying cracks on swelling and self-healing of bentonite-sand blocks used as engineered barriers for radioactive waste disposal

Experiments were conducted to evaluate the healing of drying cracks in air-dried bentonite-sand blocks after hydration and swelling in groundwater,providing justifications to simplify the protection of blocks prior to installation in a high-level radioactive waste repository.Synthetic groundwater was prepared to represent the geochemistry of Beishan groundwater,and was used to hydrate the blocks during the swelling pressure and swelling strain measurements,as Beishan is the most promising site for China's repository.Healing of the surface cracks was recorded by photography,and healing of the internal cracks was visualized by CT images and hydraulic conductivity of air-dried blocks.The results indicate that the maximum swelling pressure and swelling strain are primarily affected by the geochemistry of Beishan groundwater,but not affected by the drying cracks.The maximum swelling pressure and swelling strain of air-dried blocks are comparable to or even higher than the pressure and strain of fresh blocks.The maximum swelling pressure measured in strong(i.e.high ion strength)Beishan groundwater was 44%of the pressure measured in deionized(DI)water,and the maximum swelling strain was reduced to 23%of the strain measured in DI water.Nevertheless,the remained swelling of the blocks hydrated in strong Beishan groundwater was sufficient to heal the surface and internal drying cracks,as demonstrated by the pictures of surface cracks and CT images.The hydraulic conductivity of the air-dried block permeated with strong groundwater was comparable(3.7×higher)to the hydraulic conductivity of the fresh block,indicating the self-healing of drying cracks after hydration and swelling in groundwater.A simplified method of protecting the block with plastic wraps before installation is recommended,since the remained swelling of the block hydrated in Beishan groundwater is sufficient to heal the drying cracks.

The leaching behavior of simulated HLW glass under repository condition

As the multibarrier system has been adopted to dispose HLW glass in geological formation in many coun- tries, it was important to study the leaching behavior of vitrification under geological formation. This article describes the leaching behavior of simulated high level waste glass (90Nd/10), which can incorporate 16 wt.% simulated HLW in five kinds of geological media, such as granite, cement, bentonite, Fe3O4, etc. The durable experimental results show that the glass had less mass loss in granite and more mass loss in bentonite after a two-year leaching test. The SEM/XEDS analysis shows some element distributions on the leached specimen’s surface, i.e., Na, Si and Mg ele- ments were reduced on the specimen’s surface, whereas Ba, Al, and Fe were enriched on the specimen’s surface.

Modeling the leaching behavior of simulated HLW-glass using PHREEQC

PHREEQC is a geochemical model to study aqueous ion reaction equilibrium in water systems. In this paper, PHREEQC was used to calculate concentrations of main elements (Si, Na, B, Al, Sr, Cs, Fe and Nd) leached from simulated HLW-glass in solution. The experiments were preformed in deionized-water or simulated underground water at 90℃ or 150℃ under low oxygen atmosphere. The calculated results agreed well with the experimental results.

Synthesis of SrTiO_3 for immobilization of simulated HLW by SHS

Strontium titanate synroc samples were synthesized by self-propagating high-temperature synthesis （SHS）. Sr directly took part in the synthesis process. As a result, the loading content issue is basically resolved. The products were characterized by density, microhardness X-ray diffraction, and scanning electron microscopy （SEM/EDS）. The leaching rate was measured by the method of PCT （product consistency test）. The results indicate that the Sr^2＋-SrTiO3 compound is of high density, low leach rate and high stability and the synthesis process is feasible in technology and economy. It can be concluded that the strontium titanate synroc is a perfect material to immobilize HLW.

Design and validation of the THMC China-Mock-Up test on buffer material for HLW disposal

According to the preliminary concept of the high-level radioactive waste （HLW） repository in China, a large-scale mock-up facility, named China-Mock-Up was constructed in the laboratory of Beijing Research Institute of Uranium Geology （BRIUG）. A heater, which simulates a container of radioactive waste, is placed inside the compacted Gaomiaozi （GMZ）-Na-bentonite blocks and pellets. Water inflow through the barrier from its outer surface is used to simulate the intake of groundwater. The numbers of water injection pipes, injection pressure and the insulation layer were determined based on the nu- merical modeling simulations. The current experimental data of the facility are herein analyzed. The experiment is intended to evaluate the thermo-hydro-mechano-chemical （THMC） processes occurring in the compacted bentonite-buffer during the early stage of HLW disposal and to provide a reliable database for numerical modeling and further investigation of engineered barrier system （EBS）, and the design of HLW repository.

THM Coupled Modeling in Near Field of an Assumed HLW Deep Geological Disposal Repository

One of the most suitable ways under study for the disposal of high-level radioactive waste (HLW) is isolation in deep geological repositories. It is very important to research the thermo-hydro- mechanical (THM) coupled processes associated with an HLW disposal repository. Non-linear coupled equations, which are used to describe the THM coupled process and are suited to saturated-unsaturated porous media, are presented in this paper. A numerical method to solve these equations is put forward, and a finite element code is developed. This code is suited to the plane strain or axis-symmetry problem. Then this code is used to simulate the THM coupled process in the near field of an ideal disposal repository. The temperature vs. time, hydraulic head vs. time and stress vs. time results show that, in this assumed condition, the impact of temperature is very long (over 10 000 a) and the impact of the water head is short (about 90 d). Since the stress is induced by temperature and hydraulic head in this condition, the impact time of stress is the same as that of temperature. The results show that THM coupled processes are very important in the safety analysis of an HLW deep geological disposal repository.

高放废物地质处置缓冲材料砌块吊装转运及包装工艺的研究进展

在施工安装期,最大限度保护砌块的完整性和安全性,确保缓冲材料原位试验安装技术顺利进行,开展缓冲材料砌块转运和包装技术研究是基础保障。通过调研芬兰、瑞典和日本高放废物处置库缓冲材料砌块的吊装转运及包装工艺流程及设备。初步查明:芬兰和瑞典将制备好的砌块放置在托盘上,转运到轨道运输机或传送带将托盘转运到储存室,区别在于瑞典现场安装以起重安装装置和吸盘为主;日本在处置单元砌块现场安装试验中,采用起重机和机械夹持装置进行吊装,同时考虑砌块加工凹槽和使用辅助带防止砌块掉落;瑞典、芬兰在砌块包装均采用塑料膜包装或者将堆放在托盘上的砌块整体采用塑料膜包装;日本砌块包装采用塑料膜包装。研究表明:采用真空吸吊机可以完成大型砌块吊装转运及安装;小型缓冲材料砌块采用塑封袋包装和大型缓冲材料砌块采用塑料膜包装,能满足缓冲材料砌块临时储存要求。

北山花岗岩裂隙围岩蚀变矿物学及地球化学特征

在地质流体的作用下,花岗岩裂隙两侧常发生不同程度的围岩蚀变,蚀变可能会改变围岩的矿物组成、化学组分乃至对放射性核素的阻滞性能。因此,查明深部岩体裂隙围岩的蚀变特征是处置库场址评价的重要内容之一。以北山新场和沙枣园花岗岩体深钻孔岩心为调查对象,借助显微分析、X射线荧光法等分析测试手段,研究分析了裂隙两侧岩石蚀变的矿物学及地球化学特征,初步探讨了蚀变作用对于围岩还原能力的影响。研究结果表明:北山花岗岩裂隙蚀变岩仅在少数裂隙两侧分布,主要类型为因矿物交代作用引起的钠长石化、黏土化、赤铁矿化和绿泥石化等,每种蚀变作用过程使得围岩的矿物组分与化学组成发生特定变化,除Na_(2)O、K_(2)O、CaO、Fe和LOI等元素以外,其他主量元素含量在蚀变作用中变化微弱或无变化。仅从Fe(Ⅱ)含量变化上分析,北山花岗岩裂隙蚀变作用对围岩还原能力的影响很小。

模拟高放废物地质处置条件下锝在去离子水体系中的胶体行为

^(99)Tc是高放废物地质处置中重点关注的关键核素,深地质处置条件下其在地下水中的胶体行为对其迁移行为可能存在较大影响,亟需系统开展研究。本文在模拟高放废物地质处置的低氧和低浓(氧气含量小于5 ppm、^(99)Tc初始浓度10^(-9)~10^(-5) mol/L)条件下,首先探讨了用膜过滤法研究锝胶体行为的可行性,发现pH值和离子强度等对^(99)Tc的液闪测定无明显影响,且过滤器对Tc(Ⅳ)和Tc(Ⅶ)均无显著吸附行为,基于此初步建立了锝胶体行为研究的膜过滤实验方法,并采用该方法研究了去离子水体系中锝的胶体行为。结果表明:Tc(Ⅶ)不易发生水解反应,在低氧条件下无明显胶体行为,并能长期稳定地存在于体系中,可能具有较强的迁移能力;Tc(Ⅳ)易水解而聚集为胶体,在较宽pH值范围内(pH=4~11)以真胶体形式在398 d实验周期内较长期地稳定存在于体系中,其浓度高于以离子形态存在的Tc(Ⅳ)的数倍甚至1个数量级,所形成的胶体可能会提高地质处置条件下Tc(Ⅳ)的迁移能力,但体系离子强度升高会使Tc(Ⅳ)胶体易凝聚为大颗粒物质甚至沉淀,导致锝以真胶体形态存在和迁移的可能性降低,因此高放废物处置中,锝胶体行为对其迁移行为的影响应予以足够重视和研究。

高放玻璃固化体浸出行为的机器学习预测模型研究

高放玻璃固化体在长时间深地质处置下与地下水接触,导致放射性核素浸出,因此其浸出行为的预测对提升高放核废物固化安全至关重要。本研究采用人工神经网络(ANN)、卷积神经网络(CNN)和时序卷积网络(TCN)三种机器学习模型结合ALTGLASS数据库,对玻璃固化体浸出行为预测模型进行训练和测试。研究结果表明,TCN和ANN模型分别对玻璃固化体中的部分元素表现出较好的预测准确性,而CNN对于玻璃固化体元素浸出行为预测适用性较差。对Cr、Si、Li、B、Al、Mg、Ca元素的浸出行为预测上,TCN模型表现出最高的准确性。K、Na、Fe和Mo元素浸出行为的预测,则是ANN模型预测吻合度最优。根据研究结果,TCN和ANN浸出模型结合能较好地预测玻璃固化体的浸出行为。本研究为高放玻璃固化体服役过程中化学稳定性的预测提供了新的技术方法。

二次自蔓延高温合成钙钛矿固化^(90)Sr

采用二次自蔓延高温合成(SHS)技术制备钙钛矿固化高放废物90Sr,通过XRD,SEM和PCT粉末浸泡法,研究了钙钛矿固化体的微观组织、浸出率以及其对高放废物90Sr的最大包容量。结果表明,固化体样品密度高、孔隙率小,浸出率都小于0.1 g/(m2.d),对SrO的包容量可达36%(质量分数);表明自蔓延高温合成的钙钛矿人造岩石固化体化学稳定性好、包容量大,是固化高放废物的理想固化体。

用SHS将核废物固定于类矿石

分析了钛酸锶 (SrTiO3)的晶体结构和性能 ,利用自蔓延高温合成反应生成钛酸锶 (SrTiO3) ,使Sr2 + 直接参与合成反应 ,从根本上解决了Sr2 + 包容量的问题。通过多种现代分析技术研究了钛酸锶固化体的物理、化学性能。结果表明固化体样品密度高、孔隙率小、浸出率低且稳定性高 ,技术和经济上可行。

北山花岗岩岩屑-膨润土混合材料导热性能研究

高放废物地质处置库缓冲/回填材料的重要作用之一是传导和散失高放废物衰变热,在膨润土中添加石英砂、石墨、花岗岩岩屑等导热性能较好的添加剂是提高缓冲/回填材料导热性能的主要方法。选用北山花岗岩岩屑为添加剂,与高庙子钠基膨润土GMZ01组成混合材料,制备不同含水率、不同密度的试样。使用Hot Disk TPS2500s热常数分析仪测定样品的导热系数,分析其与花岗岩岩屑含量、干密度、饱和度等参数的关系,并运用多种混合物热传导模型分析预测导热系数。研究结果表明,花岗岩岩屑能够有效提高缓冲/回填材料的导热性能,混合材料的导热系数分别与其饱和度、气体体积存在线性关系;Maxwell方程能够较好预测北山花岗岩岩屑-膨润土混合材料的导热系数。

混合型缓冲回填材料膨胀力试验研究

与纯膨润土相比,混合型缓冲回填材料(膨润土与石英砂混合物)能够实现防渗阻隔能力、热传导性能、力学强度和可施工性能的最佳组合。选用高庙子钠基膨润土(GMZ001)为缓冲回填材料的主料,添加不同比例的石英砂,对掺砂比分别为0、10%、20%、30%、40%和50%的膨润土-砂混合物压实试样进行室内试验。结果表明,混合物的液限、塑限随掺砂率的增大而线性降低;膨胀力随时间呈指数增长。初始含水率较大时,最大膨胀力随初始含水率的增大略有降低。掺砂率一定时,最大膨胀力随初始干密度指数增长。提出了有效黏土密度的概念,建立了一定初始含水率条件下,任意掺砂率和初始干密度的高庙子膨润土-砂混合物最大膨胀力归一化模型,为混合型缓冲回填材料膨胀力的预测与控制提供了依据。

北山深部花岗岩弹塑性损伤模型研究

基于力学特性试验和三维声发射监测技术,研究北山花岗岩在压应力条件下的力学行为特征和损伤演化机制,并构建岩石的力学损伤模型。试验结果表明,在低围压条件下岩石主要发生的是脆性破坏;随围压增大,岩石力学行为逐渐向延性转化,表现出剪胀、塑性变形等非线性行为。结合微裂隙产生和扩展规律,对岩石在外力作用下的损伤演化过程和破坏机制进行分析,认为北山花岗岩的破坏及非线性行为是损伤和塑性变形共同作用的结果。基于这一认识,在热动力学框架下提出北山花岗岩准唯象弹塑性损伤模型。模型引入非关联的塑性流动方程,以反映岩石在压应力作用下体积变形从压缩到膨胀的转化过程。基于已有的损伤理论建立损伤演化方程,并通过在塑性屈服面中引入独立损伤变量,建立塑性和损伤发展的耦合关系。数值模拟和试验数据的对比表明,模型可以很好地描述北山花岗岩在不同应力水平下的损伤演化规律和力学行为,特别是随围压增大岩石力学行为从脆性到延性的转化过程以及岩石峰前塑性硬化和峰后应力软化等行为特征。

高放废物处置库花岗岩热-力耦合模拟研究

根据典型高放废物处置库概念模型,应用FLAC3D有限差分程序模拟计算了数百年内热–力耦合(TM)条件下高放废物地质处置库围岩的温度场、应力场和变形场的变化特征,初步得到在一定废物罐热源强度及衰变函数条件下花岗岩体的热力学特征及处置巷道工程设计的合理间距。模拟结果表明:在-500m水平建造处置库,按设定的释热强度,处置坑合理间距为8～12m,废物罐表面温度为130℃,处置坑中线岩体最高温度为40℃,并保持数百年左右。