01 March 2024, Volume 41 Issue 3

    

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  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 0-0.

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Special Contribution
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  Thickness of Glacier and Frozen Soil in the Source Region of Changjiang River Based on GPR Detection

  ZHOU Li-ming, ZHANG Yang

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 1-8. https://doi.org/10.11988/ckyyb.20231225

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  Changes of glacier in the source region of Changjiang (also known as Yangtze) River reveal the climate change trends in the Qinghai-Xizang (Tibetan) Plateau. Subglacial topography is crucial for understanding glacier development and movement processes, and is, furthermore, of guiding importance for the soil and water conservation and freshwater resource reserves in the source region of Changjiang River. Based on a decade of scientific expedition and research on the source region, the Changjiang River Scientific Research Institute accurately measured the glacier thickness on the main peak of Geladandong in 2022 and 2023 by employing ground-penetrating radar (GPR). We also conducted investigations on the upper limit of permafrost thickness in the Chatan Wetland. In association with numerical simulations of GPR wave field by multiple glacier and permafrost geological models, we have enhanced the effectiveness and accuracy of GPR in detecting glacier and permafrost in the source region. The findings manifest that both the glacier thickness on the main peak of Geladandong and the upper limit of permafrost in the Chatan Wetland have experienced varying degrees of decline. Long-term observations of glacier thickness and permafrost upper limits are essential and must be continued in order to accumulate more data and analyze trends, thus estimating ice reserves in the detection area and investigating the impacts of climate change on glaciers.
River-Lake Protection And Regulation
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  Impacts of the Poyang Lake Water Conservancy Hub Project on Hydrodynamic Process in Flood Period of Yangtze River and Poyang Lake

  LIU Yu-jiao, YU Ming-hui, HUANG Yu-yun, WU Hua-li

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 9-15. https://doi.org/10.11988/ckyyb.20221510

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  Poyang Lake, which connects to the Yangtze River, has historically suffered from frequent flooding, with the flood process being influenced by various factors. The construction of the Poyang Lake Project (PLP) will bring about alterations to the complex hydrodynamic processes in flood periods. This study aims to examine the impacts of PLP using a two-dimensional hydrodynamic model. The severe flood in 1954 and the backward flow in 1991 were selected as scenarios to simulate the potential impacts with and without the PLP. The findings indicate that the PLP will moderate the discharge process at Hukou and reduce the peak flood value, while leaving the water level in the Yangtze River unchanged. In the scenario of the severe flood in 1954, PLP raises the water level in Poyang Lake, resulting in a maximum water level increase of 0.021 m at representative hydrological stations. Conversely, in the scenatio of backward flow in 1991, PLP reduces the water level in the lake region. The fluctuation pattern of water level aligns with the discharge process at Hukou, while the phase of water level slightly lags behind the flow process. The research outcomes offer technical support for ensuring the safety of both the Yangtze River and Poyang Lake.
Water Resources
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  Groundwater Utilization and Countermeasures of Groundwater Overexploitation in the Yangtze River Basin

  LIU Xin, XIAO Hua, WANG Dong

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 16-21. https://doi.org/10.11988/ckyyb.20230700

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  The utilization and development of groundwater in the Yangtze River Basin remain relatively limited. Nonetheless, groundwater resources continue to play an essential role in preserving the ecological balance of rivers and lakes, addressing sudden water safety challenges, and supporting agricultural production. Drawing on groundwater exploitation and stage data from 2011 to 2020, we examined the current status and trends in groundwater utilization, stage variations, and the issue of over-exploitation in the Yangtze River Basin. Our findings reveal that shallow groundwater serves as the primary source of extraction in the basin, with a gradual decline in overall extraction levels. With few exceptions, groundwater stages across the basin have demonstrated stability or a modest increase. Over the period from 2011 to 2020, area of over-exploitation were predominantly concentrated in Nanyang City,Henan Province,where groundwater stages exhibited a declining pattern. This underscores the urgent need for the implementation of alternative water source projects to mitigate irrigation water shortages.
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  Reconstruction of Water Surface Energy Balance and Evaporation Model under Floating Ball Coverage

  XU Si-yuan, YAN Xin-jun, WANG Hai-tao, SHI Ke-bin

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 22-29. https://doi.org/10.11988/ckyyb.20221405

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  To address the issue of low water resource utilization caused by intense evaporation in plain reservoirs in arid regions,we have chosen black high-density polyethylene floating balls as a means to combat evaporation and promote water conservation.This study examines the response mechanism of water surface evaporation and the distribution of water energy balance components under floating ball coverage throughout the non-freezing period using theoretical analysis,modeling,and outdoor experiments.On this basis,we developed a calculation model of water surface evaporation.Our results indicate that,when compared to uncovered water surfaces,the overall net radiation absorption rate decreases by approximately 12.6% under a 73% floating ball coverage.The average monthly latent heat flux required for evaporation decreases by 61.8% to approximately 148.73 W/m².The sensible heat flux and heat storage flux of water body also experience significant changes.By accounting for modifications in energy and aerodynamic terms,our model for calculating surface evaporation under covered conditions demonstrates high precision.
Water Environment And Water Ecology
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  Fish Trajectory Extraction Based on Landmark Detection

  SHI Xiao-tao, MA Xin, HUANG Zhi-yong, HU Xiao, WEI Li-si

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 30-36. https://doi.org/10.11988/ckyyb.20221436

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  The existing fish trajectory extraction methods fail to balance efficiency and accuracy. This study introduces a fish trajectory extraction approach based on fish landmark recognition and location utilizing the RetinaFace algorithm. The method entails constructing a fish trajectory extraction model through enhanced network structure and loss function for landmark detection, optimizing anchor size design, and encoding and decoding fish landmarks (specifically, the head point and centroid point). Additionally, it involves supplementing landmarks of fish targets with extra labels and generating a fish key point dataset. The findings demonstrate that the proposed research method achieves high accuracy in identifying fish landmarks, with precision evaluation indices including an accuracy rate of 97.12%, a recall rate of 95.72%, and a mean average precision of 96.42%. Moreover, the average relative deviation of the extracted trajectory coordinates is MREx(0.065%,0.092%) and MREy(0.112%,0.011%), aligning closely with the actual swimming trajectory of fish. The recognition rate for landmarks of fish targets reaches 32 frames per second, which meets the real-time extraction requirements for fish trajectory recognition.
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  Spatial-temporal Distribution and Influencing Factors of Dissolved Oxygen in the North Mainstream of Dongjiang River

  WANG Ju, WU Qiong, LUO Huan, SUN Ling-ling, LI Ning, HE Ying-qing

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 37-44. https://doi.org/10.11988/ckyyb.20221362

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  The North mainstream of Dongjiang River is located at Guangzhou’s eastern drinking water source protection zone, with a target water quality of Class II. The Dadun section, as the last assessed section designated by the government in the North mainstream, holds significant importance in evaluating the overall water quality. However, the dissolved oxygen (DO) level in this section have failed to meet required standards over the past five years. We collected water quality data from the mainstream of Dongjiang River and the Dadun section during 2018-2022 and analyzed the temporal and spatial variations of DO concentration. Using Pearson correlation analysis and multiple linear regression analysis, we investigated the causes of low oxygen levels in the Dadun section based on recent hydrometeorological data and water quality remote sensing images. Our results revealed that the DO concentration in the lower reach of the north mainstream was significantly lower than that in the upper and middle reaches. Additionally, the DO concentration was higher during dry seasons compared to wet seasons. The DO concentration in Dadun section were influenced by numerous factors. It positively correlates with pH value, conductivity, and tidal current velocity, while negatively correlating with water temperature, total phosphorus (TP), turbidity, and rainfall. Furthermore, the upstream incoming water quality plays a crucial role in affecting the DO concentration of the north mainstream. Among these factors, water temperature emerges as the primary influencing factor, contributing 62.1% to the overall DO concentration variation. The research findings provide essential support for ensuring the stability of the Dadun section during national assessments, and moreover, contribute to strengthening the region’s capacity for water pollution prevention and control, ultimately enhancing the effectiveness of water pollution management efforts.
Soil and Water Conservation and Ecological Restoration
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  Spatial-temporal Evolution and Patterns of Production-Living-Ecological Space of Nanzhai Terraces in Qingshui River Valley

  WANG Hua-fei, ZHAO Yu-luan, YANG Xiao-piao, ZHAO Jia

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 45-53. https://doi.org/10.11988/ckyyb.20221340

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  In the context of rapid urbanization, the traditional terraced agricultural cultural landscape in mountainous areas is experiencing severe degradation and the need for sustainable development. Therefore, it is of practical significance to clarify the spatial-temporal patterns and evolution rules of the production-living-ecological space in terraced areas for the protection and development of agricultural landscapes in mountainous regions. Taking the Nanzhai terraces in Qingshui River Valley as a case study, we employed GIS spatial data, Participatory Rural Assessment (PRA), terrain niche index, and land use transfer matrices to analyze the spatial-temporal evolution and pattern characteristics of the production-living-ecological space from 2000 to 2020. The results are as follows: 1) In terms of quantity change, the production space has decreased in area, while the living and ecological spaces have expanded. 2) Regarding pattern evolution, the production space exhibits a ladder distribution pattern with significant aggregation and weak dispersion. Notably, a contraction trend is in the southern and eastern parts of the study area. The living space tends to expand in a dispersed manner from the central aggregation point towards the periphery. The ecological space spreads along both banks of the Qingshui River, and when intersecting with production and living spaces, it exhibits fragmented distribution characteristics. 3) Concerning changes in topographic distribution, the production space has shifted towards medium-high terrain gradients, while shrinking on low terrain gradients. The living space has shifted towards medium and low terrain gradients. In terms of the ecological space, there is a concentration trend towards low topographic gradients. 4) As for area transfer behavior, frequent transfers occur among the production, living, and ecological spaces. Notably, the main characteristics include the outflow of production space and the inflow of living space and ecological space.
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  Differential Analysis of the Relationship between Land Surface Temperature and Near-surface Air Temperature in Karst Area and Non-karst Area

  LIAO Meng-yao, LUO Ya, YU Jun-lin, WANG Qing, SHI Chun-mao, XU Xue

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 54-61. https://doi.org/10.11988/ckyyb.20221605

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  The relationship between land surface temperature and near-surface air temperature serves as a critical foundation for understanding the interaction between subsurface and near-surface atmosphere, and is also vital for maintaining efficient energy circulation and enhancing climate environment. The natural characteristics of karst areas substantially differ from those of non-karst areas, resulting in divergent patterns of energy transfer between land and atmosphere in these distinct environments. Based on pairwise nearest-neighbor pixel selection, we acquired land surface temperature and near-surface air temperature data for Ziyun and Wangmu counties in southwest Guizhou from 2000 to 2018. Subsequently, we compared and analyzed the discrepancies between karst and non-karst areas. Our findings indicate that: 1) The disparities and fluctuations between land surface temperature and near-surface air temperature are more pronounced in karst area than in non-karst area on an annual average basis, with greater energy transfer stability observed in non-karst area. 2) In seasonal scale, the difference between land surface temperature and near-surface air temperature is more prominent in karst area than non-karst area during spring, summer, and autumn, albeit not in winter. Additionally, the fluctuation of the difference is greater in winter in karst area, with greater energy transfer stability in karst area throughout all four seasons. 3) As for individual months, the difference between land surface temperature and near-surface air temperature is more evident in the karst area compared to the non-karst area in each month, with greater fluctuations observed in April in the karst area. However, excluding March and April, energy transfer between land and atmosphere is more stable in non-karst area throughout the other months. The results can serve as a valuable reference for analyzing surface environmental patterns, studying climate change, and safeguarding the ecological environment.
Hydraulics
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  Secondary Flow Characteristics in Meandering Compound Channels with One-sided Floodplain Vegetation

  PAN Yun-wen, LI Zhi-jie, LIU Xin, YANG Ke-jun

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 62-70. https://doi.org/10.11988/ckyyb.20221465

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  To investigate the impact of one-sided floodplain vegetation on secondary flow in meandering channel, we designed meandering compound channels with smooth floodplains and one-sided vegetated floodplains in a generalized manner, and measured the cross-sectional instantaneous velocities using an Acoustic Doppler Velocimeter (ADV). The experimental results revealed that the formation of main vortexes in a single bend is solely influenced by centrifugal force, whereas the formation of main vortexes in the experimental meandering compound channel is closely associated with flow exchange between the floodplains and the main channel. When the relative water depth is 0.15, compared to the situation under smooth floodplain conditions, the secondary flow intensities at the apex sections with the narrowest vegetated floodplain and in crossover areas exhibit larger attenuation, but there is no apparent difference for the secondary flow intensity at apex section with the widest vegetated floodplain. For the relative depth of 0.35, the secondary flow intensity at each cross section in the meandering channel is enhanced, with the secondary flow intensity under one-sided vegetated floodplain conditions being smaller than the corresponding value under smooth floodplain conditions. In the case of one-sided vegetated floodplain conditions and the same relative depth, the secondary flow intensities in the crossover areas with a smooth upstream floodplain are notably larger than the corresponding values in crossover areas with a vegetated upstream floodplain. Under the smooth floodplain conditions, the “island center” of the cross-sectional contours of Reynolds stress R_vw can indicate the rotational center of the main vortex. The positive or negative sign of the Reynolds stress R_vw at the “island center” can reflect the rotational direction of the main vortex. Conversely, under the one-sided vegetated floodplain conditions, the R_vw contours in the cross-sectional middle parts appear disordered and do not demonstrate the aforementioned characteristics, with the absolute values of Reynolds stress R_vw being noticeably smaller than the corresponding values under smooth floodplain conditions.
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  Experimental Study on Flow Rectification Characteristics of Rough Strip Energy Dissipator in Continuous Curved Spillway

  MA Hao, MU Zhen-wei, FAN Fan, GU Yuan-hao

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 71-78. https://doi.org/10.11988/ckyyb.20221318

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  The aim of this research is to investigate the factors affecting the diversion effect of rough strip energy dissipater on continuous curved spillway and its diversion characteristics. A physical model test was conducted using an orthogonal experimental design scheme involving nine factors and three levels. The ultra-high variation coefficient (C_v) is introduced to assess the diversion effect. Dimensional analysis and multiple regression analysis were performed to examine the factors impacting flow structure, and a multi-factor influence model for evaluating the diversion effect was established. The findings indicate that the angle and height of the rough strip significantly influence the flow structure in two bends, respectively, directly impacting the effectiveness of the rough strip in balancing water level differences and stabilizing flow patterns. By eliminating less influential common factors, the optimal diversion layout scheme for rough strip energy dissipator is determined. The maximum goodness of fit for various functional models is 0.822. The fitting equation is used to compare and validate the measured values, yielding a relative error of 2.78% to 7.15%. These research findings offer theoretical insights for analyzing and rectifying the flow in continuous curved spillways.
Rock-Soil Engineering
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  Classification and Predictive Research on Excavability of Surrounding Rock for TBM Construction in Small Section with Soil-Rock Composite Geological Condition

  YANG Yao-hong, LIU De-fu, ZHANG Zhi-xiao, HAN Xing-zhong, SUN Xiao-hu

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 79-87. https://doi.org/10.11988/ckyyb.20221309

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  The efficient construction and intelligent control of TBM heavily rely on the classification and real-time identification of surrounding rock excavability. To address this, we establish a classification standard for surrounding rock excavability in TBM construction under geological conditions characterized by small sections and soil-rock combinations based on actual data (penetration thrust and torque per unit penetration) from the Anyang Western Water Diversion Project. Moreover, we introduce the PCA-RF model for real-time identification and prediction of surrounding rock excavability, and then compared the results with those of BP, SVR, and RF models. Our research yields the following conclusions: 1) The classification standard for surrounding rock excavability in TBM construction under the geological conditions of small sections and soil-rock combinations proves to be applicable. This standard resolves the limitations of traditional methods for classifying surrounding rock in soil-rock composite environments. 2) The PCA-RF model demonstrates an identification and prediction accuracy of 98.3% for the surrounding rock excavability in TBM construction under the geological conditions of small sections and soil-rock combinations. This accuracy surpasses that of the BP, SVR, and RF models and fulfills the demands of engineering construction.
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  Experimental Study on Creep Characteristics of Rockfill Material of Lianghekou Hydropower Station in High Stress State

  SUN Xiang-jun, LIU Li-qiang, DENG Shao-hui, ZUO Yong-zhen, PAN Jia-jun

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 88-93. https://doi.org/10.11988/ckyyb.20221305

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  Rockfill is the primary filling material for earth-rock dams, and its creep characteristics directly influence the magnitude of dam deformation after construction. We conducted indoor large-scale triaxial creep tests on two types of rockfill materials used in the gravel core wall of Lianghekou Hydropower Station. The findings are summarized as follows: 1) under low stress levels, the lateral strain exhibited positive values, whereas under high stress levels, the lateral strain became negative. 2) The test values at 30-year age extrapolated by using power function was utilized as the limit strain value for rockfill creep tests. Subsequently, the obtained residue creep demonstrated a robust power function relationship with time. 3) The final shear creep demonstrated a multiple relationship with shear stress, with the axial creep attenuation power index and shear creep attenuation power index being nearly equal. Moreover, the final axial creep was 1.5 times that of the final shear creep. Ultimately, we proposed a concise two-parameter power function creep model which features clear physical interpretations of model parameters and is highly practical for engineering applications. The findings provide valuable insights for the preliminary estimation of deformation following the construction of earth-rock dams.
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  Effect of Cyclic Loading and Unloading on Dynamic Characteristics of Sandstone before and after Peak Load

  WANG Rui-hong, JIA Jing-ru, LUO Hao, WEI Can, ZHANG Jian-feng, JIA Yi-hang

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 94-101. https://doi.org/10.11988/ckyyb.20221257

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  To comprehensively examine the dynamic characteristics of sandstone at different stages before and after the peak, we conducted uniaxial graded cyclic loading and unloading tests. These tests aimed to analyze the impact of the lower limit stress on various parameters, including the apparent elastic modulus, hysteretic loop area, damping ratio, damping coefficient, and dynamic elastic modulus of sandstone during the loading and unloading stages. The research findings indicate the following: 1) Due to the aggravation and accumulation of internal damage after peak, the hysteretic curve lies on the right side before the peak at the same lower limit stress. With an increase in the lower limit stress, the increments in strain and maximum strain gradually decrease. This suggests that despite limit strength has been reached after peak, cyclic loading and unloading under high-stress conditions can enhance the compactness of post-peak rock samples, as long as the rock remains intact and stable. 2) The changes in sandstone under cyclic loading and unloading before and after peak load can be observed through variations in the sloping (a) of apparent elastic modulus curve. At small lower limit stress, the coefficient of compactness enhancement (a₁) is greater than the coefficient of compactness degradation (a₂); additionally, the slope a is positive, indicating that the compressive effect of axial stress on rock mass is significantly stronger than the effect of deterioration damage. As the lower limit stress rises, the rate of decrease in a₂ is higher than that of a₁, suggesting that the compressive effect of axial stress gradually weakens compared to that of deterioration damage. 3) Under four different lower limit stress conditions, the hysteretic loop area, damping ratio, and damping coefficient are higher after the peak than before, while the dynamic elastic modulus after peak is lower than before. These findings suggest that the degree of internal deterioration damage in rock samples during cyclic loading and unloading after the peak is higher than that before the peak.
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  One-dimensional Large Strain Consolidation Analysis of Soft Soil Considering Non-Darcy Flow under Bilogarithmic Model

  LI Zhao-shuai, CAO Wen-gui, CUI Peng-lu, XU Zan, LI Hui-xin, HU Min

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 102-109. https://doi.org/10.11988/ckyyb.20221291

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  Given the limitations of semi-logarithmic model in describing the nonlinear compression and permeability relationship of large-strain soft soil, we present a bilogarithmic compression and permeability model specifically designed for such conditions. Furthermore, we established a one-dimensional large-strain consolidation equation for saturated soft soil foundation, taking into account non-Darcy flow, and provided a finite difference numerical solution. Through a comparison with indoor testing and analytical solutions, we verified the reliability of this solution. On this basis, we analyzed the effects of seepage parameters, bilogarithmic compression and nonlinear seepage parameters as well as external loads on consolidation behavior. Results indicate that, when the compression index (I_c) remains constant, greater permeability parameters lead to slower soil consolidation. Similarly, when the permeability parameter is constant, a larger compression index results in slower soil consolidation. Additionally, higher external loads (q_u) correspond to greater settlement of the soil layer, faster dissipation of excess pore water pressure, and accelerated consolidation rate. To conclude, a differential analysis of large-strain consolidation theory versus small-strain consolidation theory reveals the inapplicability of the latter in the presence of significant soil strain. Instead, the large-strain consolidation theory should be employed for accurate calculations.
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  Experimental Research on Pore Pressure and Transfer Mechanism in Clay

  TANG Yi-fan, CAO Xiao-wei, LI Ming, CUI Can, SONG Lin-hui

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 110-117. https://doi.org/10.11988/ckyyb.20221154

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  The transmission of pore water pressure in saturated clay is the foundation for analyzing geotechnical engineering problems. Delays in the transmission process and factors influencing the delay have attracted wide attentions. A testing apparatus was designed to examine the transfer of pore pressure by applying hydraulic pressure to consolidated saturated clay. Subsequently, a numerical model was established to simulate the transfer process of pore water pressure. The results reveal noticeable hysteresis in the transmission of pore pressure in saturated clay, with the duration of hysteresis increasing in proportion to the consolidation pressure. Pore water compression coefficient and soil permeability coefficient are primary factors affecting the hysteresis of pore water pressure transfer. Additionally, further numerical simulations demonstrate that an increase in pore water compression coefficient or a decrease in soil permeability leads to an extended lag time in pore pressure transfer. Specifically, when the pore water compression coefficient exceeds 10^-5 kPa^-1 and the soil permeability coefficient is lower than 10^-8 m/s, the lag time variations become more pronounced.
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  Modified Peck’s Formula for Surface Settlement of Large-section Shallow-buried Tunnel and Its Application

  MA Zhao, ZHANG Ming-li, DUAN Xu-han, ZHAO Bo

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 118-125. https://doi.org/10.11988/ckyyb.20221116

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  The classical Peck’s formula fails to account for the impact of tunnel’s section shape and buried depth on surface settlement in shallow-buried tunnels with large section. To address this limitation, we introduced a modified Peck’s formula by incorporating correction coefficients for sectional shape and buried depth, and verified the validity of the modified formula using measured surface settlement data of the Baitashan Tunnel. The average relative error between predicted and measured values for two monitoring sections is 8.3%, with a maximum relative error of 18.4%. Additionally, we employed the modified Peck’s formula to predict surface settlement resulting from tunnel excavation under various sectional shapes and buried depths. The results demonstrate a positive correlation between the maximum surface settlement and the sectional shape correction coefficient, with the following order of maximum surface settlement predicted: rectangle-1(Ⅰ) > horseshoe-1(Ⅱ) > circle (V) > rectangle-2(Ⅲ) > horseshoe-2(Ⅳ). As the burial depth of the large-section shallow-buried tunnel increases, the maximum surface settlement decreases, and the width of surface settlement groove correspondingly widens. The surface settlement curve transitions from being narrow and deep to wide and shallow, while the area of core settlement gradually diminishes. The outcomes presented in this study provide theoretical support and serve as a technical reference for similar projects.
Engineering Safety and Disaster Prevention
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  A Time Series Decomposition Method for Landslide Displacement Based on Sliding Detection Algorithm

  FENG Yu, ZENG Huai-en, TU Peng-fei

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 126-133. https://doi.org/10.11988/ckyyb.20221323

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  To address the issue of weak mechanical interpretation in the time-series decomposition model of step-type landslide displacement, we propose a decomposition method incorporating sliding R_nl step-point detection and improved weighted moving average method to modify step-term displacement. Both the Nishihara creep constitutive model and a self-adaptive improved genetic algorithm model were utilized. The proposed method was applied to decompose the displacement time series of Baishuihe landslide. The results of the proposed method were compared with those of the MK Test, sliding t test, and the Bayes test, demonstrating that the sliding R_nl step-point detection yields more accurate and applicable results. Furthermore, the displacement time series decomposition results were also compared with those obtained from quadratic moving average time series decomposition, cubic exponential smoothing time series decomposition, and VMD time series decomposition. The findings reveal that our proposed decomposition method effectively addresses irregular displacement and enhances the mechanical interpretation of the landslide trend term. Additionally, the introduction of the most critical step-term displacement in landslide displacement prediction enhances the specificity of analysis and prediction. In conclusion, our decomposition model holds significant engineering value and serves as a valuable reference for time series prediction.
Hydraulic Structure and Material
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  Revealing the Impact of Coal Gangue on Fracture Damage Characteristics of Concrete Based on Weibull Distribution

  LI Yong-jing, CHENG Yao-hui, WEN Cheng-zhang, HU Shuo, SHANG Yun-zhi, SONG Yang

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 134-141. https://doi.org/10.11988/ckyyb.20221336

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  Three-point bending tests were conducted on coal gangue concrete with I-shaped fractures. The aim was to investigate the impacts of coal gangue mass replacement rate, fly ash mass replacement rate, and water-cement ratio on load-crack opening displacement curve, load-midspan deflection curve, fracture toughness, and fracture energy. The obtained results were utilized in association with damage mechanics and the Weibull distribution function to establish the fracture damage constitutive model of coal gangue concrete. The findings indicate that the coal gangue mass replacement rate exerts the most significant influence on the fracture performance of coal gangue concrete with prefabricated I-type cracks, while fly ash mass replacement rate has a greater impact on the fracture toughness, and the water-cement ratio exhibits a greater influence on fracture energy. The optimal combination for enhancing the fracture toughness and fracture energy of coal gangue concrete is determined as follows: 25% coal gangue mass replacement rate, 10% fly ash mass replacement rate, and 0.5 water cement ratio. Upon comparison, the stress-strain curve derived from the constitutive model aligns closely with the test curve. These findings offer valuable insights for the formulation and practical application of gangue concrete.
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  Full-scale Model Test on Tensioning Technology of Prestressed Lining with Unbonded Circular Anchor

  LU An-dian, TANG Xin-wei, YAN Zhen-rui, MAI Sheng-wen, YAO Guang-liang

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 142-147. https://doi.org/10.11988/ckyyb.20221363

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  This study focuses on improving stress distribution and preventing crack formation during the tensioning process. To achieve this, we conducted full-scale model test and proposed a tension sequence and quality control indexes. Initially, we calculated the friction coefficient based on steel strand friction test. Subsequently, we applied the tension sequence and quality control indexes using an automated tension system. To monitor stress changes, we used elastomagnetic sensors for the steel strand, and strain gauges for the lining concrete. Field tensile tests yield the following key findings: 1) The steel strand experiences a prestress loss of approximately 16.3%. However, by utilizing double-layered steel strands, we ensure a highly effective prestress in practical applications. 2) Applying the proposed tension sequence in the anchorage slots results in the lining concrete achieving a relatively uniform annular compressive stress, with an average compressive stress of -10.9 MPa. 3) The three control indexes we recommend can be quantitatively managed, and when combined with automated tension technology, they effectively guarantee the quality of tension.
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  Effect of Free Mica Content of Artificial Sand on Concrete Performance

  WU Wen-bo, HE Jing-jing, WANG Hai-ting, ZHAO Kun-long, FAN Li-hao

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 148-152. https://doi.org/10.11988/ckyyb.20230401

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  The mica content of artificial sand affects its use in many areas. Present researches on the correlation between mica content and concrete performance are not comprehensive. Due to engineering safety considerations, the standards for mica content in artificial sand are overly conservative in China. As a result, artificial aggregates with high mica content are unsuitable for many hydropower projects. To promote the widespread use of artificial sand with high mica content, we propose to add free mica into artificial sand made from parent rock with high mica content. This study aims to investigate the effects of varying content of free mica in artificial sand on concrete performance. Test results demonstrate that mica content has minimal impact on the compressive strength, splitting tensile strength, and impermeability of concrete. However, as mica content increases, the unit water consumption of concrete increases, the axial tensile strength and ultimate tensile value of concrete decrease slightly, and frost resistance degrades.
Water Conservancy Informatization
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  Spatial-temporal Characteristics of Historical Drought in the Middle and Lower Reaches of Yangtze River Based on Standardized Precipitation Index and Vegetation Health Idex

  XIANG Da-xiang, JIANG Ying, CHEN Zhe, LI Zhe

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 153-159. https://doi.org/10.11988/ckyyb.20230196

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  In the middle and lower reaches of the Yangtze River, drought has had serious impacts on economic development with increasing frequency, intensity, disaster scope and duration over the past six decades. In this study, 60-year historical precipitation dataset and 40-year remote sensing dataset were constructed to calculate the meteorological drought and agricultural drought indexes. The drought monitoring index series curves were established based on standardized precipitation index (SPI) and vegetation health index (VHI). The spatial distribution, seasonal distribution, occurrence frequency and other indicators of drought were analyzed to explore the drought’s spatial-temporal differentiation laws. The results show that drought events in the study area are notably season-dependent, with high frequency in spring and summer, and low frequency in autumn and winter. Droughts in the north and west part were more serious than those in the south and east part. Northern Hubei and southern Hunan were prone to suffer from droughts.
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  Dynamic Monitoring Network with Multi-sensors for Sudden Water Pollution Events

  SHEN Shao-hong, JIANG Ying, CHEN Xi-chi, XIANG Da-xiang, CHEN Zhe, WEN Xiong-fei

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 160-165. https://doi.org/10.11988/ckyyb.20221399

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  This paper addresses the need for emergency monitoring and intelligent simulation in response to sudden water pollution events.We established the correlations of sensor performance with time,space,and attributes and constructed a multi-sensor synergetic monitoring model to accomplish the dynamic and collaborative sensing through a network of satellite,UAV(Unmanned Aerial Vehicle),ground and water platforms.We selected Danjiangkou Reservoir as a demonstration area for dynamic network monitoring of sudden water pollution events. Based on the specific observation requirements during the occurrence,dynamic evolution,and later stages of water pollution events,we determined the corresponding platforms and sensors required. Experimental results manifest that the proposed multi-sensor network captures the water pollution monitoring information comprehensively,accurately,and rapidly. Moreover,it provides scientific support for emergency response and treatment of sudden water pollution events.
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  Development and Application of Flow Capacity Checking System for Pumping Station

  CHEN Hong, HE Wen-yuan, LIU Yun

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 166-170. https://doi.org/10.11988/ckyyb.20221434

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  Long-term operation of pump station led to increased resistance and weakened outflow capacity, thereby impacting urban drainage efficiency. In view of this, we have developed a flow capacity check and evaluation system for pump stations utilizing the Python programming language and digital image technology. Real-time data of the axial flow pump voltmeter and ammeter is collected using cameras, while ultrasonic Doppler profilers and radar water level gauges record the outlet flow and head of the pump station. To address the issue of flow data deviation caused by complex flow patterns and ambient noise interference, we have implemented a moving median filtering method and employed Bessel interpolation for data completion. These methods significantly improve the accuracy of flow data. Our system has been successfully applied to assessing the outflow capacity of pumping stations, uncovering that the measured outflow capacity falls below the theoretical value in conditions where power and head remain constant.
Basic Theories And Key Technologies For Major Water Diversion Projects
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  Interaction between Large Deformation of Surrounding Rock and Support Structure in the Soft Rock Fragmentation Section of the Qinhe Tunnel of Central Yunnan Water Diversion Project

  FU Jing, WU Fan, ZHANG Yu-ting, QIN Ran

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 171-177. https://doi.org/10.11988/ckyyb.20231142

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  Large deformation of soft rock is a prominent engineering geological problem in the construction of Central Yunnan Water Diversion Project. Taking the 4th branch of the Qinhe Tunnel in Dachu segment of the diversion project as research object, we examined the characteristics of large deformation in soft rock and the stress on the bearing structure. The construction of the 4th branch has encountered recurring stability issues within the tunnel chamber. The surrounding rock has experienced varying degrees of deformation, resulting in the distortion and fracture of the steel arch frame and the detachment of sprayed concrete. To comprehensively analyze the deformation characteristics, failure modes, and their underlying mechanisms, we employed a comprehensive research approach combining engineering geological surveys, on-site monitoring measurements, numerical inversion, and construction simulation analyses. The findings indicate that, during construction at the fractured soft rock tunnel section, the surrounding rock exhibits substantial, rapid, and time-dependent deformation. The integrity of the surrounding rock is compromised, with significant variations in deformation. Shear failure predominantly affects the surrounding rock. The time-dependent deformation of surrounding rock significantly impacts the stress on the support structure, leading to local structural failures as some load-bearing structures surpass their limits. Thus, we suggest taking some effective measures when constructing tunnels in fractured soft rock. Such measures include: advance grouting, minimizing construction disturbances, promptly providing initial support, expediting ring closure, strengthening deformation monitoring during construction, selecting appropriate lining support timing, and continuously guiding and optimizing the construction design of the tunnel support structure in real time.
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  Mechanical Mechanism of Single Row of Micro Piles Strengthening Gently Inclined Long Fissured Soil Slope

  MA Peng-jie, WEI Kai, KANG Jing-wei, RUI Rui, CAI Zheng-qian, XIA Rong-ji

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 178-185. https://doi.org/10.11988/ckyyb.20221312

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  The widely application of precast concrete micro piles in the emergency reinforcement of expansive soil slope with long cracks in the South-to-North Water Diversion Project highlights their significance in ensuring slope safety. Studying the reinforcement mechanism is essential. Based on similar model test, a model was established to examine the interaction between the sliding mass and the micro single row pile in the slope with fracture surface. A thrust force was applied parallel to the fracture surface, and both similar model test and numerical simulation were conducted. The results demonstrated the effectiveness of preventing sliding by micro single row pile reinforcement. It maintained a high level of anti-sliding force in the slope system, increased slope toughness against failure, and significantly improved slope stability. The slope’s resistance to sliding decreased as the pile spacing increased. The influence of a single micro pile only extended over a limited range. As the pile spacing increased, the soil arching effect gradually weakened. Ignoring the interaction between piles became feasible when the pile spacing exceeded 12 times the pile diameter. It is recommended to maintain a pile spacing 8 times of the pile diameter. Moreover, the strengthening effect of micro piles arranged in the middle of the slope surpassed that of those arranged in the upper 1/3 of the slope.
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  Seismic and Isolation Analysis of an Elevated Large-span Beam-supported Aqueduct

  HAN Zhong-qi, AO Xuan-nian, PAN Peng, GU Wen-lan, WANG Bao-shun, LI Ke-xian

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 186-193. https://doi.org/10.11988/ckyyb.20221284

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  The site of the Central Yunnan Water Diversion Project is earthquake-prone with high seismic intensity. To ensure the safety of aqueduct facilities against earthquakes, the seismic performance of an elevated large-span beam-supported aqueduct of the Central Yunnan Water Diversion Project was analyzed. ABAQUS was utilized to establish a model of single-span aqueduct in consideration of fluid-structural interaction. Ground motion inputs were selected based on the site’s geological conditions. The elastic-plastic time-histories of aqueducts with pot-type elastomeric pad bearings (PEPBs), lead rubber bearings (LRBs), and friction pendulum bearings (FPBs) were analyzed. Results demonstrate that aqueducts with isolation bearings exhibit a 25.5% lower maximum displacement and a 24.3% smaller maximum bending moment at bottom of the pier compared to aqueducts with PEPBs. Thus, the seismic isolation performance of isolation bearings surpasses that of PEPBs, and the damages in PEPB aqueducts are more severe, primarily concentrated in the areas where the aqueducts come into contact with the bearing and at variable section of the aqueduct wall as well as at the bottom of the piers. Regarding empty aqueducts, those with LRBs experience a 10.4% larger maximum displacement than full aqueducts, accompanied by a 21.4% smaller maximum bending moment at pier bottom. On the other hand, aqueducts with FPBs demonstrate a 20.9% smaller maximum displacement and a 32.2% smaller maximum bending moment at pier bottom compared to full aqueducts. The seismic isolation period of LRBs is significantly affected by the mass of upper structure, while the period of FPBs remains independent of the mass of upper structure. Considering these factors, FPBs are found to be more suitable for aqueducts.
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  Impacts of Climate Change on Hydrological Processes in Water Source Areas of the Planning Western Route of South-to-North Water Diversion Project Based on CMIP6

  FAN Di, ZENG Si-dong, LIU Xin, YANG Lin-han, XIA Jun

  Journal of Changjiang River Scientific Research Institute. 2024, 41(3): 194-202. https://doi.org/10.11988/ckyyb.20230637

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  Studying the impact of future climate change on hydrological processes in the water source areas holds immense significance for the water transfer planning, development, and utilization of the Western Route of the South-to-North Water Diversion Project. We employ predictions from 12 General Circulation Models (GCMs) under four combination scenarios of Shared Socioeconomic Pathways-Representative Concentration Pathways (SSPs-RCPs) to drive the DTVGM model in the purpose of examining how climate change influences streamflow in the three major water source areas of the Western Route Project throughout the 21st century. The findings reveal increasing trends in the annual average temperature, precipitation, and streamflow of the Yalong River basin, Jinsha River basin, and Dadu River basin from 2021 to 2100 under SSP1-2.6, SSP2-4.5, SSP3-7.0, and SSP5-8.5 scenarios when compared to the base period. Moreover, such increment rises as radiative forcing intensifies, and the changes relative to the base period progressively amplify over time. Specifically, the Jinsha River exhibits greater interannual and decadal variability in streamflow, manifesting a more conspicuous response to climate change compared to the Yalong River and Dadu River. Predictions indicate an upward trend in monthly average streamflow in future, although variations across months are noticeable. In comparison to the base period, variations in streamflow in dry periods are minimal, while increases in wet periods are more substantial. Through correlation analysis of streamflow with temperature, and precipitation, we found that streamflow is more sensitive to precipitation, with an evident impact of precipitation on streamflow. The impact of temperature on streamflow intensifies with the rise of radiative force. The findings offer valuable insights for adapting to climate change and integrated water resource management in the water source areas of the Western Route Project of the South-to-North Water Diversion Project.