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01 November 2023, Volume 40 Issue 11
    

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    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 0-0.
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    • Special Contribution
  • A Review of Downscaling Methods for Coarse Granular Soil and Their Effectiveness
    PAN Jia-jun, SUN Xiang-jun
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 1-8. https://doi.org/10.11988/ckyyb.20230661
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    Coarse-grained soil, the primary material used in the filling of earth-rock dams, consists of particles with a maximum size reaching meter-level. However, indoor tests only allow for downscaled samples. Shrinking the scale while ensuring that the indoor test results accurately reflect the mechanical characteristics of the actual material has always been a challenge in the research of earth-rock dams. Despite significant progress in the research of downscaling methods for coarse-grained soil and their effectiveness in recent years, disagreements still exist in some specific aspects. We made a comprehensive summary and analysis of the existing methods for downscaling coarse-grained soil, as well as the boundary effects and scale effects in sample testing. Scholars in Changjiang River Scientific Research Institute present a method of downscaling coarse-grained soil by determining the density of specimens according to pressuremeter modulus equivalent to that of the actual material, which is called the method of “Equivalent Pressuremeter Modulus to Determine Density”. We further elucidate the relationship between equivalent pressuremeter modulus and consistency in mechanical properties, and expound the theoretical foundation of this method,providing technical support for researching the downscale methods for coarse granular soil.
    • River-Lake Protection and Regulation
  • Cause Analysis of Decline of Low Water Level Downstream the Dam of Xinglong Hydro-junction on Hanjiang River
    YOU Xing-ying, WANG Zu-qing, PENG Xiang-peng, WU Zheng, TANG Jin-wu
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 9-15. https://doi.org/10.11988/ckyyb.20220840
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    During the operation of the Hanjiang Xinglong hydro-junction, the water level below the Xinglong dam has experienced a cumulative decrease of 2.47-2.55 m under the flow rate of 500-800 m3/s, unfavorable for safety and operation. A comprehensive analysis reveals that the declining water level can be attributed to several factors. The Middle Route of the South-to-North Water Transfer Project and its associated compensation measures gave rise the changes of water and sediment conditions in the middle and lower reaches of the Hanjiang River. This resulted in riverbed scouring due to the clear water discharge. Additionally, the construction of the Xinglong hydroproject caused adjustments to the local river regime. Consequently, the downstream thalweg migrated back and forth, leading to bending and lengthening of the mainstream line. Furthermore, the discharge area and channel volume experienced significant increases. The implementation of waterway regulation measures also resulted in the shrinkage of the original shoal and the rapid deepening of the new main channel. Last but not the least, water diversion project from the Yangtze River to the Hanjiang River intensified the scouring force of water flow during medium and dry seasons. These factors collectively contributed to the noticeable decline in low water level in the downstream of the Xinglong dam.
  • Construction of Graded and Zonal Evaluation System for the Effectiveness of River Chief System in Jiangxi Province
    ZHANG Lei, XIE Song-hua, MO Ming-hao
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 16-22. https://doi.org/10.11988/ckyyb.20221219
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    To evaluate the river chief system in different levels and zones, we propose a matrix-based efficiency evaluation model that combines administrative grading with terrain and geomorphic zoning. Our evaluation index system for the river chief system is constructed based on seven aspects, including the six tasks of the river chief system and public involvement. We divide the index system into two levels: city and county level (18 indicators) and town and village level (16 indicators). We employ the Analytic Hierarchy Process (AHP) to determine the index weights for different characteristics of mountain and hilly areas, as well as plain and lakeside areas, and subsequently, we establish a two-level fuzzy comprehensive evaluation model to evaluate representative regions such as Ganzhou City, Nanchang City, Shangyou County, Zhangshu County, Meishui Town, and Zhangjiashan Street in Jiangxi Province. The evaluation results for these regions are categorized as good, medium, good, good, medium, and good, respectively. Our findings indicate that in hilly areas, the efficiency of the river chief system at all levels is mainly affected by water resource protection, whereas water ecological restoration influences the effectiveness of the system in Ganzhou City and Shangyou County. Additionally, water pollution control affects the effectiveness of the system in Shangyou County and Meishui Town. On the other hand, in plain and lakeside areas, water pollution control is identified as the primary factor impacting the efficiency of the river chief system at all levels. Water resource protection affects the effectiveness of the system in Nanchang City and Zhangshu County, while water ecological restoration also influences the effect in Zhangshu County. The evaluation results align well with the actual situation, affirming the suitability of our evaluation system for grading and zoning the efficiency of the river chief system.
    • Water Resources
  • Spatiotemporal Variation Characteristics of Baseflow in the Upper Yangtze River Based on Digital Filter Method
    SUN Zhi-wei, LIANG Yue, NIU Xin-qiang
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 23-28. https://doi.org/10.11988/ckyyb.20230043
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    Accurately depicting the spatial and temporal distribution characteristics of base flow in the upper Yangtze River is crucial for the rational development and utilization of water resources, particularly as it serves as a significant recharge source for river runoff during dry season. To achieve this, we combined the digital filtering method and the distributed hydrological model SWAT to analyze the time characteristics of base flow. Additionally, we employed a spatial interpolation method to describe the spatial distribution of base flow in the upper Yangtze River. The results demonstrate that the value and modulus of average annual base flow in the upper Yangtze River ranged from 5 to 9 500 m3/s and 0.36 to 28.00 L/(km2·s) during the period from 1990 to 2000. Furthermore, we found a clear positive correlation of annual runoff and base flow with annual precipitation, whereas the base flow index (BFI) shows a distinct negative correlation with annual precipitation. The BFI exhibits relatively stable inter-annual variation, with a variation within the year showing a higher base flow during the dry season compared to the wet season. This indicates the crucial role of base flow in supplying rivers. In terms of seasonal variation, summer sees the largest base flow, followed by autumn, winter, and spring in sequential order, reflecting that base flow in wet season is larger than that in dry season. Moreover, the base flow in the upper Yangtze River basin increases progressively with an increase in runoff generation and concentration area.
  • A Risk Assessment Method for Ecological Flows under Different Time Scales
    WANG Fei-long, GUO Xiao-ming, ZHANG Song, HU Ting
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 29-35. https://doi.org/10.11988/ckyyb.20220846
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    Ecological surplus (ES) and ecological deficit (ED) are indicators used to assess the ecological hydrological conditions of rivers. Previous studies have established calculation methods but lack measurable indicators to determine the extent of runoff surplus or deficiency. This paper introduces a novel method for calculating ES and ED based on discharge hydrograph (DH) as a way to evaluate river ecological runoff. The annual ES is determined by the ratio of annual runoff surplus above the 75th quantile discharge hydrograph to the annual possible maximum runoff surplus. Similarly, the annual ED is calculated as the ratio of annual insufficient runoff below the 25th quantile discharge hydrograph to the annual possible maximum insufficient runoff. Monthly and seasonal ES and ED are defined in a similar manner. Based on the ED, the ecological risk arising from reduced runoff is categorized into four levels: no risk, low risk, medium risk, and high risk. Data from the Pingshan station in lower Jinsha River were utilized to illustrate the new method. The resulting risk map presents the risk levels for each month, season, and year at the Pingshan station from 1940 to 2012. This new method overcomes the limitations of traditional approaches and provides an assessment method for designing ecological runoff control measures in the future.
    • Water Environment and Water Ecology
  • Overwintering and Recovery Process of Algae in Houguan Lake, Wuhan City
    JIA Di, XU Yuan-zhao, GONG Dan-dan, PAN Xiong, DONG Lei, LIN Li
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 36-41. https://doi.org/10.11988/ckyyb.20220797
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    From October 2021 to April 2022, we conducted on-site investigations to study the overwintering and recovery process of algae in Houguan Lake, a typical eutrophic lake in Wuhan. The results of our research indicated the presence of six phyla and twenty-six genera of phytoplankton during the overwintering period in Houguan Lake. The dominant phyla observed were Chlorophyta, Bacillariophyta, and Cyanophyta. Regarding the temporal scale, the algae abundance in water started declining in early November (autumn), remained at a low level from December to next February (winter), and displayed an upward trend from March to April (spring). In contrast, the algae abundance in sediments exhibited an initial increase from October to November, followed by a decrease until the end of January and early February. Subsequently, it began to increase again, which is a delay compared to the algae abundance in water. Such delay could be attributed to the vertical migration of algae. Correlation analysis revealed a strong response of algal cell density in both the water and sediment to changes in water temperature (p<0.01). During the overwintering, a substantial number of cyanobacterial cells settled at the lake's bottom, which indicated that the algal cell density in both water and sediment were dependent on the changes of Chlorophyta and Cyanophyta, respectively. In winter (from November to next February), the ratio of algae abundance in water to that in sediment in Houguan Lake was relatively low, indicating that most algal cells settled in the sediment during this period. Our study unveils the overwintering and recovery process of algae in Houguan Lake, thus providing essential theoretical support for understanding algal bloom mechanisms and developing prevention and control strategies.
  • Spatial Distribution Characteristics of Groundwater Chemical Composition in Shaliu River Basin of Qinghai Lake
    WANG You-cai, CAO Sheng-kui, CAO Guang-chao, KANG Li-gang
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 42-50. https://doi.org/10.11988/ckyyb.20220777
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    The spatial distribution of groundwater hydrochemical components plays a crucial role in effectively managing and safeguarding groundwater resources. Based on hydrochemical composition data obtained from the Shaliu River basin of Qinghai Lake in different typical months, we investigated the spatial distribution and heterogeneity of major groundwater hydrochemical components including anion content, pH value, and total dissolved solids (TDS) by using geological information system (GIS) spatial analysis. The findings of this study are summarized as follows: 1) Different months exhibited significant variations in the spatial distributions of anions and cations. The discrepancies in ion distributions were more prominent in June compared to January and October. Compared to January, June experienced a decrease in the extent of high-value regions for the concentrations of K+, Na+, F-, and SO42-, while an expansion in the high-value regions for Ca2+, Mg2+, and HCO-3. Conversely, the high-value and low-value regions for NO-3 content underwent no substantial changes. In October, the high-value regions for Ca2+, Mg2+, NO-3, and HCO-3 content further shrank compared to June, whereas the high-value regions for K+, Na+, F-, and SO42- contents expanded.During the study period, the spatial distribution of Cl- concentration did not change significantly. 2)The main cations in the Shaliu River basin of Qinghai Lake were affected by carbonate weathering, while silicate weathering was observed in the lower reaches of the basin. 3) Most ions in the basin roughly converged from the middle and upper reaches of the basin to the estuary, and then dispersed to the estuary delta.
    • Soil and Water Conservation and Ecological Restoration
  • Ecological Slope Protection Technology for Irrigation Canal Diverted from Yellow River
    FANG Lin, SUN Hong-xia, YANG Chun-jing, CHEN Cheng
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 51-55. https://doi.org/10.11988/ckyyb.20230521
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    Ecological slope protection serves as the primary technique for promoting slope ecological restoration and reducing geological hazards. Based on ecological environmental theory and geological disaster prevention theory, we analyzed the adaptability of commonly used ecological slope protection types. We further integrated the solidifying, protective, permeable, filtration, and flexible advantages of various slope protection types aiming to address the current challenges faced by hard slope protection in the Kaifeng segment of irrigation channel diverted from the Yellow River. In consideration of the characteristics of sandy soil and the local conditions, we propose a method of ecological slope protection by using prefabricated PET net bag box suitable for areas above the normal water level in irrigation area. To assess the feasibility of this approach, we design four test conditions and conduct performance comparisons to verify the effectiveness of the PET mesh bag box for ecological slope protection. Test results demonstrate that the shear strength of the soil mass using the PET mesh bag box is significantly enhanced compared to the original ecological slope protection, particularly the cohesion of the soil mass, which is enhanced by approximately 110%. Additionally, the PET mesh bag box exhibits notable advantages in terms of soil drainage, construction convenience, engineering cost, and ecological environmental protection when compared to concrete, slurry masonry, and six-edge bricks. These findings provide valuable insights for similar projects and contribute to the ecological protection and high-quality development of the Yellow River basin.
  • Long-time Series Ecological Quality Assessment and Influencing Factors Analysis for Changshou District, Chongqing
    LIN Na, ZHANG Di, PAN Jian-ping, FENG Shan-shan, PAN Peng
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 56-62. https://doi.org/10.11988/ckyyb.20220860
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    Studying the spatio-temporal evolution process and changing factors of ecological quality in Changshou District of Chongqing is of great significance for the ecological construction and restoration of the Three Gorges Reservoir area. In this study, we utilized Landsat-5 TM images and Landsat-8 OLI images from 2002 to 2021 and constructed the Remote Sensing Ecological Index (RSEI). With the RSEI, we investigated the evolution of ecological quality in Changshou District from both temporal and spatial perspectives. Additionally, we employed the random forest model regression to analyze the correlation between ecological quality and potential driving factors. Our findings revealed the following: 1) The average RSEI in Changshou District declined from 0.642 7 in 2002 to 0.566 5 in 2006. However, since 2010, the average RSEI has exhibited a steady increase, indicating an overall improvement in ecological quality after a previous deterioration. 2) The areas with better ecological quality mainly concentrates in higher elevation regions, whereas the industrial park, chemical industry park, and urban residential areas along the Yangtze River exhibited relatively poorer ecological conditions. 3) Over the period from 2002 to 2021, Changshou District experienced an improved area of 628.838 km2, accounting for 44.16% of the total, and a degraded area of 183.269 km2, which represented 12.87% of the total. The overall effect of ecological quality improvement was evident. 4) Through random forest regression analysis, we identified elevation and population density as the primary potential driving factors influencing RSEI changes. Moreover, human activities and terrain factors played a dominant role in regional ecological changes. As a result, RSEI and the random forest model can be effectively utilized for evaluating the ecological quality of both Changshou District and similar areas within the Three Gorges Reservoir region.
    • Water-Related Disasters
  • Excess Flood Distribution in Dongting Lake Based on Hydrological Model
    SONG Wen, WANG Jia-hu, LU Jin-you, ZHAO Wen-gang, LIU Xiao-qun
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 63-70. https://doi.org/10.11988/ckyyb.20220661
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    To quantitatively assess the distribution of excess flood volume in Dongting Lake during the inflow of floodwaters from the Jingjiang River's three diversion outlets, as well as the Xiangjiang River, Yuanjiang River, Zijiang River, and Lishui River, we establish a regional flood routing model. Our model focuses on key control sections, namely the Luoshan station in the Yangtze River's main stream, the Qilishan station in East Dongting Lake, the Lujiao station in South Dongting Lake, and the Nanzui and Xiaohezui stations in West Dongting Lake. By calibrating the parameters using typical flood data from 1996, 1998, and 2017, we calculate the distribution of excess flood volume within Dongting Lake during the 1954 flood (defense target flood for Yangtze River) before and after the Three Gorges operation. The results highlight the apparent flood regulation effect of the Three Gorges reservoir. However, even when facing the target flood, an excess flood volume of 21.5 billion m3 remains near Chenglingji, with Dongting Lake bearing an excess of 14.3 billion m3, among which the West Dongting Lake, South Dongting Lake, and East Dongting Lake bear excess flood volumes of 2.6 billion m3, 6.2 billion m3, and 5.5 billion m3, respectively. This result is equivalent to the total flood storage volume of the storage embankments in the Dongting Lake area. The findings serve as a technical reference for optimizing flood control layout in the middle reach of the Yangtze River.
  • Inundation Risk of Middle and Lower Reaches of Yangtze River Basin Based on Rainfall Scenario Simulation
    ZHANG Hong-yun, WANG Yong-qiang, WANG Da-sheng, WANG Wei
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 71-78. https://doi.org/10.11988/ckyyb.20220764
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    Given the frequent occurrence of flood disasters in the middle and lower reaches of the Yangtze River Basin, this study aims to assess the inundation risk in specific cities by simulating basin rainfall and sub-catchment areas using the Tyson polygon method and river network density method. The SCS (Soil Conservation Service) model and local equal volume method are employed to simulate the submerged depth and range under different rainfall return periods. The results highlight that the primary flooded areas in the middle and lower reaches of the Yangtze River are concentrated in the low-lying regions of the Jianghan Plain, the Dongting Lake and Poyang Lake Plain, as well as the Yangtze River Delta. With the increase in the return period of rainfall, the area affected by flooding and the severity of land flooding intensifies. There is an approximate linear relationship between the amount of rainfall and the area of inundation. For each 1 mm increase in precipitation, the submerged area expands by 947 km2 when the precipitation is below 80 mm/d and by 644 km2 when it exceeds 80 mm/d. A specific analysis conducted at city level reveals that Wuhan, Nanjing, Nanchang, and Xiaogan face high risks and large scopes of inundation. Consequently, these cities require heightened attention and defense measures.
    • Agricultural Water Conservancy
  • Impact of Informatization on Agricultural Industrial Structure Based on a Panel Model
    TIAN Tian, XIONG Yu-jiang
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 79-84. https://doi.org/10.11988/ckyyb.20230385
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    The advancement of intelligent agriculture has made informatization a vital catalyst for agricultural development. Investigating the influence of informatization on agricultural industrial structure is crucial for facilitating adjustment and upgrade in agricultural restructuring. We utilized the quadratic term of agricultural informatization development level to explore the nonlinear relationship between agricultural informatization and upgrading of agricultural industrial structure based on China's inter-provincial panel data. Furthermore, we employed the panel smooth regression model to analyze the threshold effect between agricultural informatization and upgrading of agricultural industrial structure. Results reveal that the development level of agricultural informatization exhibits an “inverted U-shaped” impact on upgrading the agricultural industry structure. The turning point of this inverted U-shaped curve represents the threshold value, which distinguishes a single threshold within the nonlinear relationship. Taking into account the actual situation of China's agricultural development, we found that the level of agricultural informatization promotes the development of the agricultural industrial structure upgrading. However, as agricultural informatization gradually rises, the driving effect would diminish marginally.
  • Spatial and Temporal Variations and Influencing Factors of Evapotran- spiration of Reference Crop in Yunnan Province Based on Cloud Model
    YANG Rui, WANG Long
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 85-92. https://doi.org/10.11988/ckyyb.20220632
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    Cloud model offers a quantitative representation of the randomness and fuzziness associated with reference crop evapotranspiration (ET0). To provide valuable insights for agricultural irrigation, flood, and drought studies in Yunnan Province, we employed cloud model to analyze the spatiotemporal distribution of ET0 in the region based on daily meteorological data from 31 meteorological stations in Yunnan spanning the period from 1958 to 2013. ET0 was calculated and examined using linear trend, partial correlation analysis, and the M-K methods. Results revealed a lack of consistency in the homogeneity of the temporal-spatial distribution of ET0 in Yunnan. The temporal variation exhibited lower homogeneity and stability compared to the spatial distribution. Over the 56 years, no significant increasing trend in ET0 was observed. However, after the year 2000, a significant upward trend in ET0 became evident, accompanied by a decrease in homogeneity and stability. Seasonally, spring exhibited the highest ET0, while winter displayed the lowest values. Notably, ET0 distribution in winter and spring appeared uneven and unstable. Spatially, the middle and south region exhibited higher ET0 values than the eastern and western and northern areas. Further analysis highlighted an increasing trend in ET0 in western Yunnan, while the middle and eastern regions experienced a decrease. The high-value areas in central Yunnan exhibited uneven and unstable variations in ET0. Additionally, our analysis identified humidity, sunshine duration, and wind speed as the primary influencing factors on ET0.
    • Rock-Soil Engineering
  • Stability Analysis of Underground Caverns and Optimization of Cavern Spacing of Kala Hydropower Station
    FANG Dan, HAN Gang, YAN Jiang-ping, SHAO Bing, ZHANG Chuan-qing, ZHOU Hui, GAO Yang
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 93-101. https://doi.org/10.11988/ckyyb.20220649
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    Unfavorable geological structures and weak strata play a decisive role in regulating the stability of surrounding rock in underground caverns at the Kala hydropower station. In light of this, a 3D fine jointed rock mass model with different levels of discontinuities and weak strata is constructed by using the discrete element method. Utilizing this jointed rock mass model, the stability of the underground caverns and optimal spacing between the main powerhouses and the main transformer room are analyzed. The numerical findings indicate favorable overall stability of the underground caverns, affirming their feasibility for construction. However, some engineering geologic concerns emerge, including significant deformation of the surrounding rock mass in the T3z2-5 weak stratum zone and block sliding triggered by joint cutting. Addressing these issues necessitates tailored support treatments. The spacing between the main powerhouses and the main transformer room is optimized via a qualitative and quantitative assessment accounting for variations in the surrounding rock field following cavern excavation as well as economic and mechanical indicators. The optimum spacing between the main and auxiliary powerhouses and the main transformer room is determined as 50 meters. Comprehensive analysis enables the identification of an optimized spacing that enhances economic efficiency and operational performance. The research findings carry substantial implications for both the optimization of cavern design and the safe construction of Kala hydropower station.
  • Impact of Lining Cracking of Compressed Air Energy Storage Cavern on Two-phase Seepage and Heat Transfer Characteristics of Fractured Surrounding Rock
    WAN Fa, JIANG Zhong-ming, LI Hai-feng, LIANG Xian-hao
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 102-110. https://doi.org/10.11988/ckyyb.20220682
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    The aim of this research is to investigate the impact of liner seal cracking on the two-phase seepage and heat transfer characteristics of fractured surrounding rock in compressed air energy storage (CAES) cavern. A dual-media two-phase seepage calculation program was developed and validated based on a weak form of PDE using COMSOL. On this basis, a numerical model was constructed to examine the impact of liner cracking on two-phase seepage and heat transfer characteristics in the fractured rock mass during gas charging and discharging processes. The findings reveal that liner cracking induces an increase in seepage pressure within both the fractures and pore spaces of the surrounding rock, and consequently leads to an amplified seepage pressure difference between the fractures and pore spaces, with a maximum pressure difference increase of 1.5 MPa. Over a period of 210 days of operation, liner cracking results in the expansion of the horizontal gas diffusion range from 54 m in the absence of cracking to 66.7 m. Under the initial gas charging and discharging conditions, a significant temperature difference exceeding 100 K can be observed between the inner and outer sides of the liner. However, liner cracking and fractures in surrounding rock exhibit minimal effects on the temperature distribution of both the liner and the surrounding rock. It is evident that while liner cracking facilitates seepage pressure diffusion, its impact on temperature distribution remains negligible.
  • Model Test on Shear Strengthening Mechanism of Stone Column Composite Foundation
    JIANG Ji-wei, SHENG Chun-hua, REN Jia-li, WANG Han-wu
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 111-117. https://doi.org/10.11988/ckyyb.20230958
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    Stone columns are commonly used in the treatment of soft foundations. However, there is a lack of quantitative research focused on their shear strength characteristics, which limits their ability to meet actual engineering needs. This study investigates the shear strength characteristics of stone column composite foundations using physical model tests and numerical experiments as the main technical methods. The following conclusions were drawn: 1) Three groups of simple shear model tests were conducted with a stone column replacement rate of 19.6% under unconsolidated, unconsolidated with flexible permeable membrane wrapped stone columns, and consolidated conditions respectively. Compared with the original soft foundation, the shear strengths of the composite foundations were significantly improved. The first two schemes showed very similar shear strength, while the consolidated scheme exhibited further improvement. This suggests that the flexible constraint of soft soil around the stone columns can enhance the overall shear characteristics of the composite foundation. The shear strength of the composite foundation was closely related to the significant improvement of permeability performance. 2) Another group of unconsolidated shear tests was conducted after increasing the replacement rate of stone columns from 19.6% to 24.5%. Compared with the consolidated shear test under a 19.6% replacement rate, the difference in shear strength was not significant. This indicates that promoting consolidation can be a more economical and effective way of improving the shear strength of the composite foundation at relatively low replacement rates. 3) Numerical shear tests of stone column composite foundations were carried out. The shear strength parameters of soil in different consolidation and drainage states were selected as the main control factor. Compared with the shear strength parameters of soil in the corresponding consolidated and drainage states, the feedback shear strength parameters of soil around columns in physical simple shear tests were improved. This verifies that stone columns significantly improve the consolidated and drainage environment of natural foundations. Overall, this study provides valuable insights into the shear strength characteristics of stone column composite foundations and proposes effective methods of improving their performance in practical applications.
  • Acoustic Emission Characteristics and Failure Precursor of Sandstone in High Temperature
    WANG Xiao-lin, WEN Shi-xuan, WANG Yu-dong, ZHANG Liang, LEI Rui-de
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 118-124. https://doi.org/10.11988/ckyyb.20220606
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    To investigate the multifractal characteristics of acoustic emission (AE) and failure precursory information in thermally-treated sandstone, we conducted indoor uniaxial compressive tests on sandstone samples subjected to different temperatures. We systematically analyzed the evolution of crack initiation stress, damage stress, peak stress, and AE characteristics throughout the failure process. The experimental results demonstrate that AE technology enables quantitative identification of crack initiation and damage stresses in thermally-treated sandstone. With increasing temperature, different crack stress thresholds exhibit a consistent evolution trend, initially increasing and then decreasing. The proportion of crack initiation and propagation gradually diminishes. As the stress level rises from 0.2σc to the post-peak stage, the width of the multifractal spectrum initially decreases and subsequently increases. This observation further confirms the structural changes occurring within thermally-treated sandstone. During the initial loading stage, the AE-b value experiences an initial increase followed by a decrease. Subsequently, as the sample approaches the unstable failure stage, the AE-b value sharply decreases, which can be considered a precursor to the instability fracture of thermally-treated sandstone.
  • Prediction of Curtain Grouting Construction Quality Based on Rough Set Theory, Salp Swarm Algorithm, and Random Forests
    SONG Ming-ming, LIU Zong-xian
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 125-130. https://doi.org/10.11988/ckyyb.20230062
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    To develop a grouting construction quality prediction model that is both highly accurate and efficient, we established a curtain grouting construction quality model based on an integration of the Rough Set Theory, Salp Swarm Algorithm, and Random Forests. The model is specifically designed for practical application in engineering projects. Comparisons were made with the SVM and BP neural network models, revealing that the proposed model achieved superior performance. Specifically, the proposed model required a mere 219.313 s for computation, and exhibited a Pearson correlation coefficient of 0.936 between predicted and measured values. Furthermore, the average absolute error, mean square error, and average absolute percentage error were measured at 0.140, 0.037, and 0.059, respectively. These findings highlight the potential of the proposed model to serve as a valuable reference for grouting construction quality control.
  • Macro-and-Micro Response Mechanism of Swelling Deformation of Red Mudstone Fillers in Southwest China
    QIU En-xi, CHEN Qiu-ling, SUN Xi-wang, ZHANG Rui, WAN Xu-sheng, QU Meng-fei, WANG Bin
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 131-139. https://doi.org/10.11988/ckyyb.20220692
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    To investigate the relationship between macro swelling and micro characteristics of red mudstone fillers, we conducted loaded and unloaded swelling tests to analyze the swelling rate and time curves of different red mudstone fillers. Additionally, we performed systematic tests on these fillers using X-ray diffraction (XRD) and scanning electron microscopy (SEM) to examine their mineral fractions and microstructures. Our aim was to establish a quantitative relationship between macro swelling and microstructure, with micro characteristic parameters as intermediate variables. The results reveal that under unloaded conditions, the swelling rate of the mudstone filler was 28.3 times that of pure mudstone, and this rate increased exponentially with the addition of montmorillonite. Upon loading, the swelling rate decreased significantly compared to the unloaded state, with a slower decrease observed for fillers with higher montmorillonite content. After the tests, clay mineral content increased by 4.57%. Furthermore, as montmorillonite content increased, the crystallinity and average crystal diameter decreased by 18.1% and 16.5 nm, respectively. The geometric characteristic parameters exhibited a linear relationship with montmorillonite content. Additionally, the number of pores with a diameter of 1-2 μm increased with higher montmorillonite dosage. Finally, we established an exponential growth relationship between swelling rate and micro characteristic parameters.
  • Experimental Study on Resistivity Structural Characteristics of Laterite During Consolidation and Compression
    PENG Guang-can, XU Xing-qian, QU Xin, ZHAO Xi, WANG Hai-jun, CAI Bo
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 140-145. https://doi.org/10.11988/ckyyb.20220645
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    Resistivity parameters related to structural properties are effective indicators of soil structure changes during compression and consolidation, and play a crucial role in quantifying these changes. We employed a modified resistivity instrument to test the vertical and lateral resistivities of Yunnan laterite during compression and consolidation. By investigating the variations of resistivity parameters (including structure factor, shape factor, and anisotropy coefficient), we aimed to analyze the changes in laterite soil structure. By using comprehensive index method and principal component analysis method, we put forward an integrated index to comprehensively evaluate the resistivity parameters related to structural properties and soil compaction. Results demonstrate that the vertical resistivity, lateral resistivity, average structure factor, and average shape factor of laterite gradually decrease as the vertical multi-stage load increases. Conversely, the anisotropy coefficients exhibit an initial decrease followed by a gradual increase to stability. Resistivity parameters indirectly reflect the structural strength and particles cementation of laterite. Additionally, the proposed comprehensive evaluation index ER is quantitatively correlated with compactness K with high fitting accuracy. In conclusion, the proposed index proves to be a feasible tool for estimating the compactness of laterite and offers a convenient approach for the rapid evaluation of compactness in rolling projects.
  • Roof Stability of Arch Tunnel in Deep Horizontal Layered Rock
    FAN Chun-tan, LIANG Qing-guo, YUE Jian-ping, LI Hai-ning, ZHOU Cai-gui
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 146-153. https://doi.org/10.11988/ckyyb.20230075
    Abstract ( ) Download PDF ( )   Knowledge map   Save
    This paper aims to investigate the calculation theory for roof stability in small section arch tunnels with deep horizontal layered surrounding rock. Based on summary and analysis of existing theory, we studied the calculation methods for the vertical relative deformation of the mid-span (vault) of layered roofs with both equal section and variable section by using the equivalent stiffness method. The results demonstrate that during the excavation of a small cross-section tunnel with horizontal layered surrounding rock, the layered roof primarily exhibits a simply supported beam model as the main stress mode. Therefore, predicting the displacement stability with a simply supported beam model is suitable for the layered roof. Additionally, when theoretically predicting the displacement stability of the layered roof, we should select the simply supported beam model with either equal section or variable section based on the actual situation. The rationality and applicability of the proposed calculation theory are verified through engineering examples and numerical simulations. Overall, the calculation theory presented in this paper effectively determines the stability of the roof in small section arch tunnels with deep buried horizontal layered surrounding rock.
  • Influence Factors of Root-Soil Composite Slope Stability during Spring Thawing
    ZHANG Xiao-rong, MA Yan-xia, ZHANG Wu-yu
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 154-159. https://doi.org/10.11988/ckyyb.20220653
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    In spring thawing period, slopes in seasonal frozen zone is susceptible to shallow slide due to thermal thawing. To investigate the stability of ecological slopes during this period, laboratory direct shear tests were conducted on the freeze-thaw interfaces of plain soil and root-soil composites. The root system was simplified as taproot type. The variation in shear strength indices of both soils was compared and analyzed. Through numerical simulation, the shear failure in the plastic zone of samples in the presence or in the absence of freeze-thaw interface was analyzed, and a model was developed to calculate the safety factor of slope stability when plant roots penetrate the freeze-thaw interface. Results indicate that as freeze-thaw cycles increase, the damage to the shear strength of plain soil at the freeze-thaw interface is greater than that of root-soil composite. Additionally, the cohesion of soil at the interface decreases, while friction angle increases for both plain soil and root-soil composite. The shear plastic zone of samples with freeze-thaw interface primarily develops within the soil body in the normal thawing zone and exhibits a significantly larger volume compared to samples with no freeze-thaw interface. By passing through the freeze-thaw interface, roots significantly raise the shear strength of the soil, thus enhancing the slope stability in spring thawing period. These findings provide a scientific foundation for the design, construction, and maintenance of ecological slope projects in seasonal frozen regions.
    • Engineering Safety and Disaster Prevention
  • Deformation Causes of Deep Excavated Expansive Soil Canal Slope during Operation Period
    HU Jiang, LI Xing, MA Fu-heng
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 160-167. https://doi.org/10.11988/ckyyb.20220795
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    Deeply excavated expansive soil canal slopes face the risk of instability during its operation period. This paper presents a case study of a moderately expansive soil canal slope, with a height exceeding 40 m, from a long-stretching water transfer project. The slope stability and the effectiveness of reinforcement measures were assessed. Multiple approaches, including safety monitoring data analysis, non-destructive detection, and numerical simulation analysis, were utilized. The deformation mechanism was evaluated by considering internal factors such as engineering geology and hydrogeology, as well as external factors like rainfall and changes in groundwater levels. The surface modified soil failed to prevent water vapor exchange between the expansive soil and the air. Moreover, during rainy season, precipitation replenished the stagnant water within the upper layer of the canal slope, resulting in a rise in groundwater levels. Conversely, the groundwater levels dropped during dry season. These cycles of drying and wetting led to the development and penetration of fissures in the canal slope. Additionally, creep deformation occurred along the fissure surface of the 2nd to the 4th slopes, influenced by both the fissure surface and the arrangement of anti-sliding piles in the water-passing section. As a result, the local slope stability did not meet specification requirements. The potential sliding surface exhibited characteristics of a combined sliding surface, with a gentle inclination angle at the leading edge and a steep inclination angle at the trailing edge. The potential shear outlet was identified at the first-level berm, although the exact location of the trailing edge of the landslide remains unclear. To enhance slope stability, a combination of drainage ditches and drainage wells proved effective as drainage measures. These findings offer valuable insights for the operation management and reinforcement governance of similar projects.
  • Method of Evaluating Dam Operation Safety Level Based on Improved Catastrophe Progression Method
    WEI Bo-wen, ZHOU Ling-kai, XU Fu-gang
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 168-174. https://doi.org/10.11988/ckyyb.20220659
    Abstract ( ) Download PDF ( )   Knowledge map   Save
    To enhance the objectivity of dam operation safety level evaluations and mitigate the influence of weight values of different monitoring effect evaluation indexes, we introduced an improved Catastrophe Progression Method. This method capitalizes on the advantage of not requiring the determination of weight values for index evaluation in assessing dam operation safety level. Additionally, we employed the entropy correction G2 method to enhance the index importance ranking process within the conventional Catastrophe Progression Method. By comprehensively considering the relative importance of each index from both subjective and objective perspectives, leveraging the essence of the G2 method and entropy method, this approach ensures a more scientifically grounded index ranking within the Catastrophe Progression Method framework, allowing it to best leverage its advantages. To validate the proposed method, it is applied to assess the safety level of a dam. The calculation results demonstrate that the method is simple, logical, and reliable, effectively determining the actual operational safety status of the dam. This outcome validates the effectiveness and practicality of the proposed method.
    • Hydraulic Structure and Material
  • Preparation and Deformation Characterization of Carbon Nanotube- Reinforced Fly Ash Foamed Concrete
    LI Yong-jing, WANG Song, ZHANG Shu-kun, FENG Dian-zhi
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 175-183. https://doi.org/10.11988/ckyyb.20220679
    Abstract ( ) Download PDF ( )   Knowledge map   Save
    To meet the mechanical performance requirements of foam concrete as the filling material for the reserved deformation layer of tunnel surrounding rock support, a novel deformable filling material called micro carbon nanotubes reinforced fly ash foam concrete (CNTAFC) was developed. The preparation parameters of CNTAFC were optimized by establishing a compressive strength prediction model using the Box-Behnken Design response surface methodology based on single factor analysis. Furthermore, the load deformation characteristics of CNTAFC specimens were investigated through a combination of uniaxial compression tests and digital speckle correlation measurement (DSCM). Results demonstrate the reasonability and effectiveness of the CNTAFC compressive strength regression model. With a CNT (carbon nanotube) content of 0.13%, a bone-cement ratio of 24.75%, and a fly ash content of 70.57%, the predicted 28-day compressive strength is 5.936 MPa, with an error of 2.54%. The CNTAFC sample exhibits improved peak strength and enhanced ductility. The average post-peak strength exceeds 60% of the peak strength, and the post-peak strain range accounts for over 30% of the ultimate strain. These characteristics satisfy the performance requirements for pressure relief and energy absorption in surrounding rock. The localized initiation of CNTAFC deformation can be distinguished under strain and stress conditions, of which the strain condition is more appropriate for determining deformation localization. When deformation localization is activated, the CNTAFC strength approaches its peak strength, and the Poisson's ratio increases significantly.
  • Chloride Diffusion in Recycled Concrete with Random Spherical Aggregates
    YAO Ze-liang, LINGHU Tian-jing, QI Ya-lun, DANG Fa-ning, WEN Shuo, CUI Ting-ting
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 184-188. https://doi.org/10.11988/ckyyb.20220593
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    Using PYTHON algorithm and COMSOL software , we have developed a three-dimensional spherical mesoscopic model for recycled aggregate concrete (RAC) based on the Monte-Carlo principle and Fuller gradation theory. The model encompasses natural aggregate, old interface transition zones (OITZ), old mortar, new interface transition zones (NITZ), and new mortar. By simulating and calculating the chloride diffusion process in RAC with varying aggregate volume fractions, old mortar diffusion coefficients, and old mortar thickness, we have examined and compared the chloride resistance of RAC. Our research demonstrates that the three-dimensional spherical random aggregate model of RAC, established through random theory, closely resembles the actual mesostructure of RAC and fulfills the requirements of general engineering. Moreover, the mesoscopic numerical simulation results for chloride diffusion based on this model are consistent with experimental findings. Specifically, when the recycled aggregate content increases from 10% to 30% and 50%, the apparent diffusion coefficients of the recycled concrete increase by 6.56% and 19.43% respectively. Additionally, the diffusion coefficient of the old mortar is quadrupled, resulting in a 19.28% increase in the apparent chloride diffusion coefficient. Furthermore, the old mortar thickness doubles, leading to an 8.1% increase in the apparent chloride diffusion coefficient. Overall, the chloride resistance of RAC weakens as the thickness and diffusion coefficient of the old mortar increase.
  • Influence of Water-based Infiltration Capillary/Crystalline Waterproof (WCCW) Material on Properties of Concrete
    ZHONG Ju-guang, GENG Bi-jun, REN Xin, LI Yang, ZHOU Shi-hua, SHI Yan
    Journal of Changjiang River Scientific Research Institute. 2023, 40(11): 189-194. https://doi.org/10.11988/ckyyb.20220563
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    Water-based infiltration capillary/crystalline waterproof (WCCW) material can repair damaged concrete and improve concrete's durability. We investigated the impact of WCCW material on early cracking resistance, compressive strength, and chloride ion corrosion resistance in concrete. Moreover, we examined the microstructure morphology of hardened cement pastes using scanning electron microscopy (SEM), the polymerization of Calcium Silicate Hydrate (CSH) gel via Fourier transform infrared spectroscopy (FTIR), and analyzed the penetration depth of WCCW material through energy-dispersive spectrometry (EDS). Experimental findings demonstrate several benefits of WCCW material, including improved appearance quality of concrete, enhanced early cracking resistance, compressive strength, and chloride ion corrosion resistance. Additionally, the material enhances the polymerization of CSH gel and increases the density of concrete. WCCW material penetrates to a maximum depth of 10 mm to 12 mm, obeying Fick's law of diffusion. The strength and curing age of concrete also affect the performance of WCCW material, and the optimal curing age is 14 days.
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Founded: 1984
Publication Frequency: Monthly
Governing Body: Changjiang Water Resources Commission, Ministry of Water Resources
Sponsor: Changjiang River Scientific Research Institute, Changjiang Water Resources Commission
ISSN 1001-5485
CN 42-1171/TV
Postal Distribution Code: 38-147
Subscription: Available at post offices nationwide
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