地热井固井材料导热性能影响因素

固井材料导热性能是影响地热井取热效果的因素之一。为提升地热井固井材料导热系数,采用正交试验,借助层次分析-指标重复性相关（AHP-CRITIC）混合加权法和极差分析,进行固井材料导热性能研究。结果表明：添加天然鳞片石墨、铁粉和石英砂均可提高固井材料导热系数,其中石墨对导热系数的提升作用最为显著,铁粉次之,石英砂最小;石墨掺量和水固比分别是影响固井材料综合性能的主次要因素;随着石墨掺量递增,其导热系数递增、48 h抗压强度和流动度均递减;得出高导热固井材料的优选配合比为：水固比值0.44,石墨、铁粉和石英砂掺量分别占水泥质量的7.5%、3%、2%,其导热系数可达1.87 W/（m·K）,较常规固井材料提高约70%。研究成果可为地热能高效开发利用提供参考。     

地磁异常二维反演与应用

文章通过一个地面磁测勘查项目,探讨了地磁异常二维反演的方法与步骤,介绍了一个实例的应用效果。     

黑海西北部冷泉碳酸盐岩的沉积岩石学特征及氧化还原条件的稀土元素地球化学示踪

黑海西北部罗马尼亚大陆架(水深120m)和乌克兰陆坡(水深190m)发育冷泉碳酸盐岩结壳。XRD测试表明此结壳主要由高镁方解石和文石组成。结壳中与渗漏系统微生物活动有关的凝块和葡萄状文石等特殊的沉积组构非常发育。冷泉碳酸盐岩酸可溶部分(碳酸盐岩相矿物)的稀土元素含量很低(0.068×10-6~2.817×10-6),稀土元素页岩标准化配分模式显示罗马尼亚大陆架冷泉碳酸盐岩具有明显的Ce负异常,乌克兰陆坡冷泉碳酸盐岩具Ce的正异常,表明它们是分别在氧化和还原环境中沉积的。稀土元素和V、Cd和U等微量元素的含量在泥晶中最高,亮晶中最低,可能反映成岩过程对元素含量有控制作用。     

南海北部陆坡西部海域“海马”冷泉甲烷渗漏及其海底表征

2015年3月"海马"号遥控无人潜水器(ROV)在南海北部陆坡西部海域首次发现活动冷泉,并命名为"海马"冷泉,此后中国地质调查局广州海洋地质调查局先后组织了3个航次,对"海马"冷泉开展进一步勘查和研究。本次研究在综合分析4个航次调查数据的基础上,初步阐述"海马"冷泉的分布范围、地形地貌、生物群落、自生碳酸盐岩和流体活动等特征。总体而言,"海马"冷泉区地势平缓,气体渗漏现象非常发育,是以CH₄为主要气体渗漏形成的活动冷泉区,且气体渗漏活动具有时空迁移性。气体碳同位素组成表明,海马冷泉区的CH₄为混合成因气,且以微生物成因为主;"海马"冷泉区发育有多种类型的化能自养冷泉生物群落,冷泉区种类丰富,目前已报道了多个冷泉生物新种。这些发现为研究南海北部陆坡西部海域天然气水合物分解及其环境效应、冷泉生物生命起源与演化和南海与印度洋及太平洋物种迁移贯通等科学问题提供重要依据。     

珊瑚颗粒形状对钙质粗粒土的压缩性能影响

珊瑚颗粒形状不规则是其显著区别于陆源土的一大特征。为揭示珊瑚颗粒形状对钙质粗粒土压缩性能的影响,人工挑选出不同形状(块状、枝状、棒状、片状)的珊瑚颗粒,以块状颗粒为基础,与其他3种不同形状的粗颗粒任意一种混合,控制不同颗粒形状配比制成钙质粗粒土试样,完成室内压缩试验,对比分析试验前后珊瑚颗粒的圆度、长宽比、扁平度和凹凸度等形状参数,评价颗粒形状对压缩性能的影响。结果表明:(1)粒径为10~20 mm钙质粗粒土的压缩模量是4~5. 5 MPa,回弹系数为42~53;(2)随枝状、棒状或片状颗粒掺量的增加(0、10%、20%、30%),试样压缩模量呈小幅波状变化,回弹系数呈持续减小趋势;(3)各加载区间应力-应变曲线包括应力快速增长阶段、应力-应变同步增长阶段、应变增长阶段共3个阶段和1个稳定点;(4)随枝状颗粒掺量的增加,试样的长宽比和凹凸度逐渐增加,圆度和扁平度基本无变化;因颗粒破碎的影响,试验后试样的长宽比及扁平度有所增加,圆度及凹凸度则有所减小。选择钙质粗粒土地基时,应考虑其压缩性能,避免施工初期的快速加载。     

全尾砂-废石混合回填膏体渗透特性试验研究

塌陷区混合回填膏体是由全尾砂、废石人工制备得到的复合宽粒级散体,其渗透性能直接影响到塌陷区回填体稳定性及次生灾害发生的可能性。采用自制的渗透性试验装置,研究了废石含量、废石粒径对混合回填体渗透系数的影响,并对回填体固有特征参数（粒径小于0.075、0.02 mm颗粒含量、不均匀系数 、平均粒径）与渗透系数之间关联性进行了研究。试验结果表明,回填膏体渗透系数随废石掺量及粒径增大而增加,细粒效应显著。回填体中粒径小于0.075、0.02 mm颗粒含量对其渗透性影响至关重要,与渗透系数呈负指数关系。渗透系数随 值增大而增大。当 20时,渗透系数增加趋于稳定。给出了混合回填体渗透系数定量方程,其结果与试验结果较为一致。     

Recent development in stratigraphic forward modelling and its application in petroleum exploration

In order to better predict the geometry and spatial distribution of reservoir facies and permeability barriers, it is critical to understand stratigraphic geometries and architecture at all scales within a basin. Stratigraphic forward modelling (SFM) allows geologists to forward project the deposition and evolution of sedimentary facies within a stratigraphic framework with given prior boundary conditions. The method can approximate depositional processes while taking into consideration a range of factors that affect basin evolution and sedimentation. This paper presents an overview of recent developments in stratigraphic forward models that are currently available and have been successfully employed in simulating stratigraphic development, including geometric models, diffusion models, Fuzzy Logic models and hydraulic models. In addition, the paper discusses SFM used in the simulation of the behaviour of natural sedimentary systems and verification of the potential for hydrocarbon entrapment and accumulation in a basin using an example from the Ordos Basin, western China.     

Theoretical analyses of acidization dissolution front instability in fluid‐saturated carbonate rocks

This paper presents an instability theory that can be used to understand the fundamental behavior of an acidization dissolution front when it propagates in fluid‐saturated carbonate rocks. The proposed theory includes two fundamental concepts, namely the intrinsic time and length of an acidization dissolution system, and a theoretical criterion that involves the comparison of the Zhao number and its critical value of the acidization dissolution system. The intrinsic time is used to determine the time scale at which the acidization dissolution front is formed, while the intrinsic length is used to determine the length scale at which the instability of the acidization dissolution front can be initiated. Under the assumption that the acidization dissolution reaction is a fast process, the critical Zhao number, which is used to assess the instability likelihood of an acidization dissolution front propagating in fluid‐saturated carbonate rocks, has been derived in a strictly mathematical manner. Based on the proposed instability theory of a propagating acidization dissolution front, it has been theoretically recognized that: (i) the increase of the mineral dissolution ratio can stabilize the acidization dissolution front in fluid‐saturated carbonate rocks; (ii) the increase of the final porosity of the carbonate rock can destabilize the acidization dissolution front, while the increase of the initial porosity can stabilize the acidization dissolution front in fluid‐saturated carbonate rocks; (iii) the increase of the mineral dissolution ratio can cause an increase in the dimensionless propagation speed of the acidization dissolution front; (iv) the increase of the initial porosity can enable the acidization dissolution front to propagate faster, while the increase of the final porosity can enable the acidization dissolution front to propagate slower in the acidization dissolution system. Copyright © 2012 John Wiley & Sons, Ltd.     

高水速凝材料-软土微观结构的SEM研究

高水速凝材料是一种新型的固体混合材料,它与普通硅酸盐水泥相比有许多独特的特点：(1) 水用量大;(2) 速凝早强;(3) 可泵时间长;(4) 良好的塑性特性;(5) 极限荷载后强度具再发展性能。虽然,高水速凝材料在煤炭和冶金系统得到了较广泛的应用,取得了较好的技术经济效益,然而,在其它领域还未曾应用过。为了探索高水速凝材料在软土地基方面的应用前景,笔者采用扫描电镜研究了高水速凝材料-软土凝固体的微观结构。研究结果表明,纯土的土颗粒之间只有原生矿物的几何堆积,而没有牢固的连接。但由于高水速凝材料的加入,彻底改变了土体结构。在高水速凝材料-软土凝固体中,主体结构为钙矾石结晶体形成的“空间网状结构”;辅助结构为在碱性环境中土颗粒之间的离子交换、团粒化作用和碳酸化作用所形成的微晶体与凝胶体结构。因此,高水速凝材料在地基处理方面具有较好的应用前景。