Strategies for Advancing Road Construction Slope Stability: Unveiling Innovative Techniques for Managing Unstable Terrain

This comprehensive review paper explores various aspects of geotechnical engineering, with a focus on the management of unstable terrains, numerical methods for solving complex soil and consolidation problems, rheological analysis of suspensions and muddy soils, and stability analysis of slopes. It begins by examining the unique physicochemical properties of cohesive sediments, including cohesion and specific surface area. The temporal evolution of deposit concentration and average bed concentration in unstable terrains is discussed, along with settling behavior of isolated particles and hindered settling using empirical equations. Key sedimentation theories, such as Kynch’s theory, and geotechnical consolidation theories, including Terzaghi’s consolidation equation and Gibson’s theory, are presented. The investigation interrelates these theories and principles to offer a holistic view of managing unstable terrains. It also addresses the challenges associated with experimental determination of constitutive relationships and presents alternative simplification methods proposed by researchers. Additionally, it delves into numerical methods for solving nonlinear partial differential equations governing soil behavior, emphasizing the need for numerical frameworks and discussing various techniques and associated challenges. The rheological analysis section covers material flow behavior, rheological behavior models, and the rheological properties of water and cohesive sediment mixtures. Fundamental geotechnical calculations, constitutive laws, and failure criteria are explained, highlighting their relevance in geotechnical engineering applications. This paper provides a multidimensional perspective on geotechnical engineering, offering valuable insights into soil properties, consolidation processes, numerical methods, rheological analysis, and slope stability assessment for professionals in the field.

The Effects of Terrain Slope and Orientation on Different Weather Processes in China under Different Model Resolutions

Currently, short horizontal surface wave radiation at the ground surface （GSW） is calculated under the assumption of a This method of estimating the GSW may lead to considerable errors when the model resolution becomes higher and the model terrain becomes steeper. In this paper, to improve the short wave solar radiation simulations, a terrain slope and orientation parameterization has been implemented into the non-hydrostatic mesoscale model GRAPES （Global/Regional Assimilation and Prediction System）. The effects of the terrain slope and orientation on different short range weather processes in China under different model resolutions are simulated and discussed. In the simulations, topography height is taken from NCEP （National Centers for Environmental Prediction） with a resolution of 1 km, and the slope and orientation of terrain are calculated using different staggering schemes and under different weather conditions. The results show that when the model resolution is low （30 and 60 km） and the slope of terrain is not large, the influence of the slope and orientation of terrain on the GSW is not evident; otherwise, however, it is not negligible. Under high model resolutions （3 and 6 km）, the increase （decrease） of simulated precipitation corresponds to the decrease （increase） of the GSW induced by the slope effect, and the variations of precipitation are usually ranged between -5 and 5 ram. Under the high resolution, the surface temperature and heat fluxes are strongly correlated to each other and the high correlation exists mostly in the complex terrain regions. The changes of the GSW, precipitation, surface temperature, and heat fluxes induced by the effects of the terrain slope and orientation are more obvious in mountainous regions, due to the alternations in the atmospheric circulation. It is found as well that under the weather condition of less cloud and less precipitation, the effects of the terrain slope and orientation can be more realistically seen. Therefore, the terrain slope and orientation can usually be neglected in numerical models when the horizontal model resolution is low and the slopes are moderate, but should be taken into account when the model resolution becomes high and the terrain is steep and undulating.

Parameterizations of the Daytime Friction Velocity, Temperature Scale, and Upslope Flow over Gently Inclined Terrain in Calm Synoptic Conditions

A set of new parameterizations for the friction velocity and temperature scale over gently sloped terrain and in calm synoptic conditions are theoretically derived. The friction velocity is found to be proportional to the product of the square root of the total accumulated heating in the boundary layer and the sinusoidal function of the slope angle, while the temperature scale is proportional to the product of the boundary layer depth, the sinusoidal function of the slope angle and the potential temperature gradient in the free atmosphere. Using the new friction velocity parameterization, together with a parameterization of eddy diffusivity and an initial potential temperature profile around sunrise, an improved parameterization for the thermally induced upslope flow profile is derived by solving the Prandtl equations. The upslope flow profile is found to be simply proportional to the friction velocity.

山区公路有限空间施工安全评价方法

山区交通工程建设经常面临狭窄地形条件下斜坡、弃渣、桥桩相互影响带来的安全挑战,需要综合评价由此产生的工程稳定问题。为了研究山区公路施工安全评价方法,依托某山区公路斜坡路段,在广泛调研狭窄地形路段工程建设特点的基础上,提出狭窄地形公路工程建设面临的共性安全问题,构建此类工程施工安全评价方法及控制标准体系,并在实际工程中应用、检验及完善该方法及指标体系。主要结果为:提出包括地基承载安全、改变地形边坡稳定性和结构安全的山区公路有限空间施工安全评价方法和安全控制标准体系。在山区公路有限空间工程建设中,需要控制弃渣填筑高度,控制加载造成的竖向应力小于承载力安全标准,实现地基承载安全;通过填筑体内部滑移、填筑体与斜坡地形接触面滑移、填筑体与自然地形深大滑移等潜在风险复核,实现边坡稳定性的全面控制;通过对桩基内力复核,控制堆载造成的结构内力小于结构承载安全标准。

SLOPE法线生成算法的LOD技术在地形渲染中的应用

为了研究LOD地形渲染技术在使用法向量进行地形光照等渲染的时候遇到的困难,解决数据存储与动态计算法线向量的问题,在分析当前使用的地形渲染技术的基础上,针对三维地形渲染的常用方法,提出了一种新的计算法线向量的方式算法,简化了操作,并提高了渲染效率.

地形对高寒草地土壤水文特征的影响

为更加合理地利用高寒地区的水资源,有效保护和恢复高寒地区植被,在甘肃连城国家级自然保护区选取不同地形(坡向、坡位)条件下的高寒草地作为研究对象,探讨不同地形条件下高寒草地0~30 cm土层土壤水文特征的变化规律。结果表明:随着土层深度增加,不同地形条件下高寒草地土壤含水量降低,土壤容重增大;从不同坡向来看,阴坡土壤含水量高于阳坡,土壤容重则相反;从不同坡位来看,坡下部土壤含水量和土壤容重高于坡上部。土壤总孔隙度、毛管孔隙度和非毛管孔隙度均为阴坡大于阳坡、坡上部大于坡下部,三者均表现为阴坡上部最高。不同地形条件下,高寒草地的土壤持水能力大小为阴坡>阳坡,坡上部>坡中部>坡下部。土壤初始入渗率(0.47~5.90 mm·min^(-1))高于稳定入渗率(0.08~1.36 mm·min^(-1))和平均入渗率(0.09~1.54 mm·min^(-1)),不同地形条件下,高寒草地的土壤渗透率表现为阳坡>阴坡,坡上部>坡中部>坡下部。地形(坡向、坡位)对高寒草地的土壤水文特征有不同程度的影响,因此,在甘肃连城国家级自然保护区对高寒草地生态系统进行生态保护与恢复、可持续发展建设的过程中,应充分考虑地形与土壤水文特征的相互关系。

凸出部放大效应在桥址高边坡地震稳定性评价中的应用探讨

深切峡谷区桥址高边坡凸出部具有三面临空和多面卸荷的典型地质地貌特征,研究边坡凸出部地震地形放大效应对桥址边坡安全控制尤为重要。依托特大桥桥址高边坡,研究了地震作用下边坡凸出部放大效应和变形破坏机制,优化了墩台位置。研究结果表明:(1)现场调查和数值模拟综合印证了边坡凸出部山顶碎屑流和主墩下部危岩体发育,受历史震害强。加速度随坡高呈现非线性放大的规律,开挖加剧了挖方区域加速度放大效应。凸出部(坡脊)坡腰和坡顶位置放大系数最大,加速度放大系数M_(PGA)最大可达3.2。(2)坡脊高频部分(5~12 Hz)的加速度傅里叶谱幅值普遍比坡谷大,开挖导致墩台上(下)边坡的傅里叶幅值的峰值减小在(增大)。开挖位置附近的傅里叶谱幅值的峰值均随峰值加速度的增加呈现先增大后减小的趋势。(3)《建筑抗震设计规范》中限制了最大坡高和放大系数极值,可能造成高边坡凸出部的动力放大效应被低估,使得凸出部地震稳定性评价结果偏危险。(4)为保证桥址边坡的地震稳定性,采用文中所述方法优化墩台外侧距坡面的距离为22~26 m。研究成果可为有凸出部的高边坡地震稳定性评价和墩台位置优化设计提供指导。

岛礁地形上斜坡堤前破碎波流场数值模拟研究

基于SPH方法建立波浪数值水槽,对岛礁地形上的波浪传播变形进行了数值模拟,分析了岛礁地形上波浪破碎过程的波高和水质点波动流速分布,并采用波浪水槽物理模型试验数据进行对比验证。结果表明,该模型可以较准确地模拟岛礁地形上波浪破碎引起的波高和波动流场沿程变化。在此基础上模拟了礁坪上建设斜坡堤后的波动流场,分析了斜坡堤对礁坪上流场形态、沿程波高、波动流速垂向分布及近底流速的影响。结果表明:在建设斜坡堤后,礁坪上波浪破碎更加猛烈,波浪破碎点前移;沿程波高与波动流速受反射波影响明显,沿程波高变化呈现为先增大、再减小、再增大,最后在防波堤堤脚处减小,近底流速变化趋势则与之相反;在堤前半倍波长范围内反向近底流速峰值较非岛礁地形上规范公式计算值增幅较大。

高原湖泊流域建设用地坡谱演变研究--以滇池流域为例

高原湖泊流域因受自然地理条件限制较大,建设用地不可避免地出现“向湖”“爬坡”扩张现象,通过构建建设用地坡谱可有效揭示其时空演变规律。以滇池流域为例,基于2000—2020年土地利用数据和基于DEM转化的海拔数据,借助陡峭度、均匀度、上限坡度等方法分析了坡谱演化特征,提出了加权爬坡指数(WBCI)以定量表征建设用地爬坡程度,并结合海拔区间的视角探究了建设用地扩张的空间分异及演变规律。结果表明:①滇池流域建设用地扩张显著,呈现以滇池北岸主城区为主核心,东岸呈贡区、南岸晋宁区为次核心的建设用地分布格局;②建设用地垂直空间扩张呈现两阶段特征,即先平地扩张后爬坡扩张。2000—2015年为向湖、降海拔扩张阶段(WBCI<0);2015—2020为爬坡、升海拔扩张阶段(WBCI>0)。③建设用地坡谱演变与海拔变化在流域尺度具有一致性,即爬坡指数变化趋势与建设用地分布的平均海拔变化趋势高度一致。但在区县尺度,建设用地爬坡扩张与海拔爬升存在明显的空间差异性。研究为城镇空间二维扩展向三维扩展提供新的思考和视角,也可为城镇空间用地规划及其生态环境效应评估提供支撑借鉴。

倾斜地面3D点云快速分割算法

依赖于平面拟合或局部几何特征区分地面障碍物的方法广泛应用于自动驾驶领域,但是在具有倾斜地形或稀疏数据的情况下,性能会降低。在倾斜地形场景中,利用激光雷达(LiDAR)提供的点云数据,通过地面点云的3D投影与直线拟合,利用栅格地图方法降低计算复杂度,实现地面点云的分割。针对非地面的点云集合,利用SLR聚类算法处理,通过设定强度特征阈值在垂直方向区分地面点与非地面点,并对扫描到的障碍物地面分类。通过实验分析,提出的算法较其他地面点云分割算法,一方面在倾斜地形上具有更好的建图效果,另一方面SLR聚类算法处理后的强度特征在X、Y、Z三个方向覆盖范围更精确,如在X方向相较于快速地面分割算法平均提高了44.0%,相较于添加了栅格地图的算法平均提高了40.1%。

山地光伏支架安装技术

光伏电站的建设可充分利用太阳能等可再生能源,大大减少对环境的破坏,对改善大气环境有积极地作用。工程建设中光伏构件安装存在诸多不利的因素,因此工程建设中应采取合理的措施以减小工程建设的损失。依托永仁麦冲河125MW复合型光伏项目,阐述了山地陡坡地形如何精确、快速地安装光伏构件和注意措施,探讨光伏构件安装技术。

Evaluation on Terrain-Climate Superiority Degree at County Level in Yunnan Province

Terrain slope and climate zone(heat zone)are important factors affecting land use zoning and agricultural production layout in mountainous areas.Using"weight grade method",a quantitative index of comprehensively evaluating terrain slope and climatic(thermal)conditions in mountainous areas was proposed:terrain-climate superiority degree(TCSD),and TCSD,terrain superiority degree(TSD),and climate superiority degree(CSD)in 129 counties(cities and districts)of Yunnan Province were measured and analyzed.The results showed that TCSD in 50.39%of counties of Yunnan Province was relatively better(levels I and II),and TCSD in 38.76%of counties was moderate(level III),while TCSD in 10.85%of counties was relatively poorer(levels IV and V).

坡度点烧实验中床层宽度对林火蔓延的影响

本研究在实验室内构件目标林分下的可燃物结构床层并进行点烧试验,通过改变点烧平台的坡度与宽度值,分析有坡点烧实验中不同床层宽度对火线燃烧轨迹、林火蔓延速率的影响。实验包括四种床层坡度(0°、10°、20°、30°)和三种床层宽度(1、2、3 m),每场点烧进行两次共24场点烧实验。将本研究结果与现有相关经典模型预测值对比后,给出合理的床层宽度范围,在保证点烧实验精度的前提下,以期为今后的相关研究提供参考。

基于模型履带板的斜坡最大剪应力计算模型构建与验证

在山地斜坡路面工况下,履带拖拉机行走系对土壤施加的最大剪应力是拖拉机高效行驶的动力基础,由于经典的库伦公式未考虑履带剪切速率、斜坡角度、土壤含水率等实际因素的影响,不能直接应用于履带拖拉机在斜坡路面工况下的行驶力学计算。针对该问题,在不同土壤含水率条件下进行了直剪试验,得到土壤抗剪强度参数随含水率变化的数学模型。采用二次旋转正交组合试验,探究了履带板在不同剪切速率及斜坡角度下对土壤最大剪应力的影响规律,并对经典库伦公式进行修正。验证试验表明,在不同土壤含水率、剪切速率和斜坡角度条件下,最大剪应力试验值与理论值之间的相对误差均<5%,表明修正后的库伦公式可准确反映各因素对最大剪应力的影响,可为履带拖拉机在斜坡路面工况下的行驶力学计算、性能分析提供理论依据。

复杂地形条件下充填工艺研究及应用

在构建高效绿色环境友好型矿山指导思想下,全尾砂胶结充填采矿法因其具备处理尾砂及控制围岩变形、降低开采对地表环境影响的优点,成为了矿山安全、高效、绿色开采的关键支撑技术,得到了全面的推广应用。在矿山应用过程中,尾砂料浆多采用管道运输,而在以陡峭山谷为主的复杂地形条件下,特别是长距离、大落差、反坡输送过程中,极易出现堵管、爆管,甚至损坏输送泵等问题,成为了限制大规模充填的瓶颈问题。本文以武里蒂卡金矿为例,在开展系统性试验研究获取完整充填试验数据的基础上,结合矿山总图布置特点、地形条件及采空区空间相对区域位置等因素,进行尾砂输送方案对比优选,首次提出适应大落差山地条件的压滤尾砂缆车运输再造浆充填工艺方案,并在现场成功实施和运行。矿山生产运行情况表明:单套充填系统即可满足矿山3 000 t/d的生产需求,充填料浆似膏体态,系统运行稳定,配比参数精准,充填质量有保障。压滤尾砂缆车运输再造浆工艺方案具有流程短、占地少、效率高、运行经济可靠等优点,在大落差山地条件下该充填工艺能够实现充填物料高效运输、制备及低成本充填,具有较好的推广应用意义。

大坡度复杂地形柔性光伏支架施工方法研究

随着光伏行业的不断发展,光伏发电项目建设将面临复杂山地地形,而传统的光伏支架无法适用于复杂地形条件。笔者以玉溪市易门县铜厂乡底尼25 MW光伏发电项目为依托,开展山地柔性光伏支架施工技术研究,重点对大坡度、复杂地形条件下柔性光伏支架施工工艺和安装质量控制等进行研究,并对柔性光伏支架的施工方法和施工工艺进行总结,以期为类似项目建设提供借鉴。

基于DEM的坡位图生成方法

本文探讨基于数字高程模型(Digital Elevation Model,简称DEM)的坡位图生成方法,主要包括DEM数据采集和预处理,生成山谷图、脊部图、平地图、上中下坡位图,整合生成坡位一张图等技术。使用该技术可以实现DEM数据向坡位图的转换,为地形分析和林业应用提供数据支持。

浅谈大坡度、复杂地形光伏电站灌注桩施工质量控制

笔者针对大坡度、复杂地形中的地质条件复杂、灌注桩长度确定难、施工难度大等难题,提出灌注桩施工质量控制要点,并详细阐述灌注桩施工关键工序的实施和控制,对常见施工事故提出相应处理和预防措施。这些措施的实施能够显著提高施工质量和效率,降低成本,并确保光伏灌注桩基础的稳定性和承载性能,为光伏电站的可靠运行提供坚实的基础保障。

Simulation on slope uncertainty derived from DEMs at different resolution levels:a case study in the Loess Plateau

Slope is one of the crucial terrain variables in spatial analysis and land use planning, especially in the Loess Plateau area of China which is suffering from serious soil erosion. DEM based slope extracting method has been widely accepted and applied in practice. However slope accuracy derived from this method usually does not match with its popularity. A quantitative simulation to slope data uncertainty is important not only theoretically but also necessarily to applications. This paper focuses on how resolution and terrain complexity impact on the accuracy of mean slope extracted from DEMs of different resolutions in the Loess Plateau of China. Six typical geomorphologic areas are selected as test areas, representing different terrain types from smooth to rough. Their DEMs are produced from digitizing contours of 1:10,000 scale topographic maps. Field survey results show that 5 m should be the most suitable grid size for representing slope in the Loess Plateau area. Comparative and math-simulation methodology was employed for data processing and analysis. A linear correlativity between mean slope and DEM resolution was found at all test areas, but their regression coefficients related closely with the terrain complexity of the test areas. If taking stream channel density to represent terrain complexity, mean slope error could be regressed against DEM resolution (X) and stream channel density (S) at 8 resolution levels and expressed as (0.00158+0.031S-0.0325)X-0.0045S2-0.155S+0.1625, with a R2 value of over 0.98. Practical tests also show an effective result of this model in applications. The new development methodology applied in this study should be helpful to similar researches in spatial data uncertainty investigation.

New Method for Estimating Daily Global Solar Radiation over Sloped Topography in China

A new scheme for the estimation of daily global solar radiation over sloped topography in China is developed based on the Iqbal model C and MODIS cloud fraction. The effects of topography are determined using a digital elevation model. The scheme is tested using observations of solar radiation at 98 stations in China, and the results show that the mean absolute bias error is 1.51 MJ m-2 d-1 and the mean relative absolute bias error is 10.57%. Based on calculations using this scheme, the distribution of daily global solar radiation over slopes in China on four days in the middle of each season （15 January, 15 April, 15 July and 15 October 2003） at a spatial resolution of 1 km×1 km are analyzed. To investigate the effects of topography on global solar radiation, the results determined in four mountains areas （Tianshan, Kunlun Mountains, Qinling, and Nanling） are discussed, and the typical characteristics of solar radiation over sloped surfaces revealed. In general, the new scheme can produce reasonable characteristics of solar radiation distribution at a high spatial resolution in mountain areas, which will be useful in analyses of mountain climate and planning for agricultural production.