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Automatic extraction of geological discontinuities of a tunnel surface by integrating multiple features 通过整合多种特征自动提取隧道表面的地质不连续性
IF 6.7 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Pub Date : 2024-09-13 DOI: 10.1016/j.tust.2024.106072

In water conservancy, transportation, and mining projects, the timely acquisition of geological structural information from tunnels is critical in the analysis of engineering geological problems during the investigation and construction stages. The acquisition of comprehensive and accurate geological information from a tunnel surface remains challenging. This study provides an automatic extraction method for geological discontinuities on a tunnel surface by integrating 2D textural semantic features and 3D geological semantic features. A dense point cloud is generated using multiline parallel sequence images, after which the 3D geological semantic features, including the local geological attitude, are calculated. Through a virtual projection from 3D to 2D, the red, green, and blue (RGB) images and geological semantic images based on views of the interior umbrella arch and the sidewalls of the tunnel surface are obtained. The feature mapping between the 2D textural semantic features and the 3D geological semantic features is determined accordingly. The virtual RGB images and geological semantic images serve as dual inputs for ensemble learning for pixel block segmentation, and the output is a similarity probability tensor that describes the probability that each pixel will belong to its surrounding pixel blocks. The pixel blocks are clustered on the basis of pole and contour plots of their geological attitudes to extract geological discontinuities. Experiments were conducted to confirm and evaluate the feasibility and veracity of the proposed method. The developed method automatically extracts geological discontinuities of a tunnel surface and extends the scope of surveying and mapping through geological remote sensing.

在水利、交通和采矿工程中,及时获取隧洞地质结构信息对于分析勘察和施工阶段的工程地质问题至关重要。从隧道表面获取全面、准确的地质信息仍然具有挑战性。本研究通过整合二维纹理语义特征和三维地质语义特征,提供了一种隧道表面地质不连续性的自动提取方法。利用多线平行序列图像生成密集的点云,然后计算包括局部地质姿态在内的三维地质语义特征。通过从三维到二维的虚拟投影,可获得基于内部伞拱和隧道表面侧壁视图的红、绿、蓝(RGB)图像和地质语义图像。据此确定二维纹理语义特征与三维地质语义特征之间的特征映射。虚拟 RGB 图像和地质语义图像作为像素块分割集合学习的双重输入,输出为相似性概率张量,描述每个像素属于其周围像素块的概率。像素块根据其地质态度的极点和等高线图进行聚类,以提取地质不连续性。为了证实和评估所提出方法的可行性和真实性,我们进行了实验。所开发的方法可自动提取隧道地表的地质不连续性,扩大了地质遥感测绘的范围。
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引用次数: 0
Study of the Physiological Characteristics of Drivers Facing Apparent Changes in Highway Tunnel Structures 面对公路隧道结构明显变化的驾驶员生理特点研究
IF 6.7 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Pub Date : 2024-09-13 DOI: 10.1016/j.tust.2024.106050

The increasing frequency of structural damage and reinforcement repairs in long-term highway tunnels necessitates an understanding of their effects on drivers. This study examines drivers’ physiological responses to visible structural changes in highway tunnels. Using a vehicle static in-the-loop platform, we created various models of apparent tunnel structure changes for simulated driving experiments. These experiments enabled a detailed analysis of the effects of such changes on driver safety, utilizing metrics such as eye movements, regions of interest, heart rate, and vehicle speed. The results show that visible alterations in tunnel structures significantly affect drivers’ physiological responses. Structural spalling and fire residues within tunnel structures notably increased drivers’ vigilance and psychological stress, resulting in a 14.7% increase in the average number of fixations, a 26.35% increase in the average duration of fixations, and a 36.05% increase in heart rate variability. Additionally, tunnel spalling tends to cause drivers to accelerate or exceed the speed limit, with maximum speeds reaching 17.87% above the designed speed. In contrast, repairs involving cover arch erection had minimal impact on drivers, with eye movement and heart rate data similar to those in ordinary tunnels. However, reinforcement with steel strips and corrugated steel in tunnels has attracted significant attention, with the area of interest exceeding 50% of the tunnel area, potentially leading to distracted driving. This study clarifies the extent of the influence of visible tunnel structure changes on drivers, providing a reference for damage assessment, reinforcement, and repair measures for long-term operated tunnels.

长期高速公路隧道结构损坏和加固维修的频率越来越高,因此有必要了解其对驾驶员的影响。本研究探讨了驾驶员对高速公路隧道中可见结构变化的生理反应。利用车辆静态在环平台,我们创建了各种明显的隧道结构变化模型,用于模拟驾驶实验。这些实验利用眼球运动、感兴趣区、心率和车速等指标,详细分析了这些变化对驾驶员安全的影响。结果表明,隧道结构的明显变化会极大地影响驾驶员的生理反应。隧道内的结构剥落和火灾残留物明显提高了驾驶员的警惕性和心理压力,导致平均注视次数增加了 14.7%,平均注视时间增加了 26.35%,心率变异性增加了 36.05%。此外,隧道剥落往往会导致驾驶员加速或超速,最高车速比设计车速高出 17.87%。相比之下,涉及盖拱架设的维修对驾驶员的影响很小,眼球运动和心率数据与普通隧道相似。然而,隧道中的钢带和波纹钢加固引起了极大的关注,关注面积超过了隧道面积的 50%,有可能导致驾驶者分心。本研究明确了可见隧道结构变化对驾驶员的影响程度,为长期运营隧道的损伤评估、加固和修复措施提供了参考。
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引用次数: 0
Optimized deep learning modelling for predicting the diffusion range and state change of filling projects 预测灌装项目扩散范围和状态变化的优化深度学习模型
IF 6.7 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Pub Date : 2024-09-11 DOI: 10.1016/j.tust.2024.106073

Concealment of filling constructions poses significant challenges for quality assurance in filling engineering. Direct surveillance of fill dispersal currently remains infeasible, while conventional detection techniques suffer deficiencies in efficiency. This research proposes a framework integrating elastic wave monitoring and hybrid deep learning for predictive modelling of filling state transitions and diffusion range. During the sand filling of the immersed tunnel, elastic wave data is collected via elastic wave testing, and the response energy characteristic is derived through time-domain analysis. The trends in elastic wave response energy are correlated with three filling states: free diffusion, accumulation, and filled state, using Seasonal and Trend decomposition using Loess (STL) for seasonal trend analysis. Convolutional Neural Networks (CNN) and Long Short-Term Memory Networks (LSTM) are utilized to extract spatiotemporal features from the response energy trends, facilitating accurate prediction of the trends’ development and the sand filling state over time. The performances of the proposed strategy are illustrated through an application to the case study of the sand filling construction of the Chebeilu immersed tunnel. The CNN + LSTM model with the proposed strategy gave excellent results (MAE 0.0663, MSE 0.0071, RMSE 0.0845). The model can predict fill state changes and quantify diffusion radii to optimize and guide the construction process.

填充结构的隐蔽性给填充工程的质量保证带来了巨大挑战。目前,直接监控填料扩散仍不可行,而传统的检测技术在效率上也存在缺陷。本研究提出了一种整合弹性波监测和混合深度学习的框架,用于预测填土状态转换和扩散范围的建模。在沉管隧道灌砂过程中,通过弹性波测试收集弹性波数据,并通过时域分析得出响应能量特征。利用黄土季节和趋势分解法(STL)进行季节趋势分析,将弹性波响应能的变化趋势与自由扩散、堆积和填充三种填充状态相关联。利用卷积神经网络(CNN)和长短期记忆网络(LSTM)从响应能量趋势中提取时空特征,有助于准确预测趋势的发展和随时间变化的充沙状态。通过对车北路沉管隧道填砂施工案例的应用,说明了所提策略的性能。采用所提策略的 CNN + LSTM 模型取得了优异的结果(MAE 0.0663,MSE 0.0071,RMSE 0.0845)。该模型可以预测填充状态变化并量化扩散半径,从而优化和指导施工过程。
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引用次数: 0
R-C-D-F machine learning method to measure for geological structures in 3D point cloud of rock tunnel face 用 R-C-D-F 机器学习方法测量岩石隧道工作面三维点云中的地质结构
IF 6.7 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Pub Date : 2024-09-11 DOI: 10.1016/j.tust.2024.106071

This study introduces an innovative Roughness-CANUPO-Dip-Facet (R-C-D-F) methodology for the measurement of dip angle and direction in geological rock facets. The R-C-D-F method is distinguished by its comprehensive four-step approach, encompassing filtration through roughness analysis, CANUPO analysis, and dip angle filtration, followed by facet segmentation as the measurement step. To achieve precise and efficient results, the method specifically focuses on isolating joint embedment, achieved by systematically filtering out joint bands. This selective filtration process ensures that measurements are conducted exclusively on relevant joint embedment points. The novelty of this methodology lies in its capability to automatically eliminate joint bands while retaining the joint embedment points, facilitating precise measurements without manual intervention. Three site models were evaluated using the R-C-D-F method, alongside four different techniques for measuring dip angle and direction: plane fitting, normal vector conversion, facet segmentation, and compass measurements. The results demonstrated that all methods accurately calculated the dip angle, with an accuracy ranging from 97 % to 99.4 %. The facet segmentation method was selected as the optimal measurement tool due to its automatic nature and capacity to provide accurate results without manual intervention. Furthermore, the optimal local neighbour radius (LNR) for calculating normal vectors was determined, with findings indicating that a larger LNR value enhances accuracy but also increases computational time. A verification was conducted to estimate the dip angle used for filtering and discarding additional points representing joint rock bands, with the optimal value being 45, 30, and 45 degrees for the respective sites.

The R-C-D-F method effectively detected and eliminated 100 % of joint band points while retaining 81 % of joint embedment points, and the facet segmentation method provided accurate dip angle and direction measurements for each joint embedment segment. These outcomes underscore the robustness and precision of the R-C-D-F method in geological engineering and rock stability studies.

本研究介绍了一种创新的粗糙度-CANUPO-倾角-切面(R-C-D-F)方法,用于测量地质岩石切面的倾角和方向。R-C-D-F 方法的独特之处在于其全面的四步方法,包括粗糙度分析过滤、CANUPO 分析和倾角过滤,然后将面分割作为测量步骤。为了获得精确高效的结果,该方法特别注重通过系统过滤掉接合带来隔离接合嵌入。这种选择性过滤过程可确保只对相关的关节嵌入点进行测量。该方法的新颖之处在于能够自动消除连接带,同时保留连接嵌入点,从而无需人工干预即可进行精确测量。使用 R-C-D-F 方法以及四种不同的倾角和方向测量技术:平面拟合、法向量转换、切面分割和罗盘测量,对三个场地模型进行了评估。结果表明,所有方法都能准确计算倾角,准确率在 97% 到 99.4% 之间。切面分割法由于其自动性和无需人工干预即可提供精确结果的能力,被选为最佳测量工具。此外,还确定了计算法向量的最佳局部邻接半径(LNR),结果表明,LNR 值越大,准确度越高,但也会增加计算时间。R-C-D-F 方法有效地检测并剔除了 100% 的关节带点,同时保留了 81% 的关节嵌入点,而面分割方法则为每个关节嵌入段提供了精确的倾角和方向测量值。这些成果凸显了 R-C-D-F 方法在地质工程和岩石稳定性研究中的稳健性和精确性。
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引用次数: 0
A novel longitudinal bending model of shield tunnel based on discretization of fiber section under the coupling of multiple factors 多因素耦合下基于纤维截面离散化的新型盾构隧道纵向弯曲模型
IF 6.7 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Pub Date : 2024-09-10 DOI: 10.1016/j.tust.2024.106063

The longitudinal equivalent bending stiffness (LEBS) typically exhibits nonlinearity under the coupling of multiple environmental and construction loads. In this research, we propose the Circumferential Joint Fiber Section Model (CJFM) to analyze the longitudinal bending behavior affected by critical factors such as geometric, material, and contact nonlinearities, and the influence range of the circumferential joint. The performance of CJFM is then verified via classical analytical solutions and laboratory model experiments. Furthermore, the applicability of the proposed model is further confirmed based on the Zhanjiang Bay undersea tunnel in China. The results show that the CJFM accurately simulates the full evolution process of seven modes and employs different constitutive models. The longitudinal stress of typical section in Zhanjiang Bay undersea tunnel reveals a distinct pattern of alternating tension and compression from top to bottom, with a noticeable temporal variation of five stages. Utilizing the CJFM, a safety partition of bending mode is constructed, ranging from healthy to unsafe. Upon the estimated bending moment and axial force, the safety status of the test ring is consistently evaluated to be in normal service, and it is inferred that the subsequent state in future will maintained in normal service under similar circumstances.

纵向等效弯曲刚度(LEBS)在多种环境和施工荷载的耦合作用下通常表现出非线性。在这项研究中,我们提出了圆周连接纤维截面模型(CJFM),用于分析受几何、材料和接触非线性等关键因素影响的纵向弯曲行为,以及圆周连接的影响范围。然后通过经典的分析解法和实验室模型实验验证了 CJFM 的性能。此外,还以中国湛江湾海底隧道为基础,进一步证实了所提模型的适用性。结果表明,CJFM 可精确模拟七种模式的完整演化过程,并采用了不同的构成模型。湛江湾海底隧道典型断面的纵向应力从上到下呈现出明显的拉伸和压缩交替模式,并有明显的五个阶段的时间变化。利用 CJFM,构建了从健康到不安全的弯曲模式安全分区。根据估算的弯矩和轴向力,试验环的安全状态被一致评估为正常使用,并推断在类似情况下,其后续状态将保持正常使用。
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引用次数: 0
Analysis method of radon release during underground cavern excavation 地下洞穴挖掘过程中氡释放量分析方法
IF 6.7 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Pub Date : 2024-09-10 DOI: 10.1016/j.tust.2024.106062

Radon release during underground engineering excavation is mainly from the newly generated fracture surfaces of the rock mass rupture, and the accurate prediction of radon release depends on the quantitative characterization of the rock mass rupture. To examine the correlation between radon release and rock mass rupture, a series of triaxial compression radon release tests were carried out and the effective radon exhalation rate (Jeff) was defined, a linear function of rock fracture area and radon release was developed. Based on the continuous-discontinuous element method (CDEM), a quantitative equation between rock fracture degree (D) and radon release by numerical model for triaxial compression tests was obtained. Subsequently, a synthetic rock mass (SRM) method combining discrete fracture network (DFN) model and CDEM was used to analyze the scale dependence of radon release from rock mass rupture, and the representative element volume (REV) size of the radon release from rock mass rupture was determined. Radon release increases exponentially with increasing sample size. Radon release increases and then decreases with the increase of joint dip angle, however, radon release increases with the increase of joint trace length amplification factor. Additionally, an underground powerhouse excavation model to derive the evolution of radon release from the surrounding rock with the number of excavation layers was established. The results of this research can provide a basis for radon pollution control during underground engineering excavation.

地下工程开挖过程中的氡释放主要来自岩体破裂新产生的断裂面,而氡释放的准确预测取决于岩体破裂的定量特征。为了研究氡释放与岩体破裂之间的相关性,进行了一系列三轴压缩氡释放试验,并定义了有效氡呼出速率(Jeff),建立了岩石断裂面积与氡释放的线性函数。基于连续-非连续单元法(CDEM),通过三轴压缩试验数值模型得到了岩石断裂程度(D)与氡释放量之间的定量方程。随后,采用离散断裂网络(DFN)模型与 CDEM 相结合的合成岩体(SRM)方法分析了岩体破裂时氡释放量的尺度依赖性,并确定了岩体破裂时氡释放量的代表元素体积(REV)大小。氡释放量随着样本大小的增加呈指数增长。氡释放量随节理倾角的增大先增大后减小,但氡释放量随节理痕迹长度放大系数的增大而增大。此外,还建立了地下发电厂开挖模型,以推导围岩中氡释放量随开挖层数的变化情况。该研究成果可为地下工程开挖过程中的氡污染控制提供依据。
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引用次数: 0
Strengthening effect of the CFRP method on fire-damaged segments CFRP 法对火灾受损路段的加固效果
IF 6.7 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Pub Date : 2024-09-09 DOI: 10.1016/j.tust.2024.105871

To reveal the strengthening effect of the CFRP method on the fire-damaged segment. In this study, the fire-damaged segment was strengthened with the CFRP-PCM method and CFRP-sheet method, respectively. The crack development, deformation characteristics, failure mode, load-bearing behaviour and internal force evolution of the segment specimens were analysed. The results indicated that the CFRP-PCM method can improve the crack development of the segment, while the CFRP-sheet method can only prevent the crack initiation of the segment before tearing between the CFRP sheet and the segment. The fire-damaged segment strengthened by the CFRP-PCM method exhibited gradual deformation and failure characteristics, whereas the fire-damaged segment strengthened by the CFRP-sheet method exhibited sudden failure with no discernible damage characteristics. The CFRP-sheet method had a higher initial strengthening effect on the fire-damaged segment than the CFRP-PCM method before tearing between the CFRP sheet and the segment, while the strength utilisation rate of the CFRP grid was higher than that of the CFRP sheet. The CFRP method of strengthening the fire-damaged segment can improve the tensile strength of the tension zone, increase the sectional stiffness, and restore the load-bearing capacity; however, this comes at the expense of the deformation capacity. The study provides a reference value for the strengthening design of fire-damaged linings in shield tunnels.

揭示 CFRP 方法对火灾受损段的加固效果。本研究分别采用 CFRP-PCM 法和 CFRP 片材法对火灾损坏段进行了加固。分析了裂缝发展、变形特征、失效模式、承载行为和内力演变。结果表明,CFRP-PCM 方法可以改善节段的裂纹发展,而 CFRP 片材方法只能在 CFRP 片材与节段之间撕裂之前阻止节段裂纹的产生。采用 CFRP-PCM 方法加固的火灾损坏区段表现出渐进变形和破坏特征,而采用 CFRP 片材方法加固的火灾损坏区段则表现出突然破坏,没有明显的损坏特征。与 CFRP-PCM 方法相比,CFRP-片材方法在 CFRP 片材与火灾受损段之间发生撕裂之前,对火灾受损段的初始加固效果更高,同时 CFRP 网格的强度利用率高于 CFRP 片材。CFRP 加固火灾受损区段的方法可以提高受拉区的抗拉强度,增加截面刚度,恢复承载能力;但这是以牺牲变形能力为代价的。该研究为盾构隧道火损衬砌的加固设计提供了参考价值。
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引用次数: 0
Equivalent continuous numerical simulation of a large-scale underground powerhouse excavation considering the size effect of the jointed rock mass 考虑节理岩体尺寸效应的大型地下发电站挖掘工程等效连续数值模拟
IF 6.7 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Pub Date : 2024-09-07 DOI: 10.1016/j.tust.2024.106058

For the stability analysis of the surrounding rock mass of an underground powerhouse, reliable mechanical parameters of the rock mass and appropriate analysis methods are highly important. This paper discusses the rationality of using the mechanical parameters of the representative volume element (RVE) of a jointed rock mass as equivalent mechanical parameters and using the equivalent continuity method to simulate the excavation of a large underground powerhouse in a jointed rock mass, with the underground powerhouse of the Wuyue pumped storage power station as an example. Initially, the discrete fracture network (DFN) and synthetic rock mass (SRM) of the jointed rock mass were established. The size of the RVE of the rock mass was determined to be 23 m × 23 m × 23 m through numerical tests. The mechanical parameters of the RVE were used as the equivalent mechanical parameters of the rock mass. Then, the two-dimensional numerical calculation of the excavation of the main powerhouse was carried out using the equivalent continuous method and the discontinuous method. The mean relative error between the deformation of the surrounding rock calculated by the two methods is 8.24 %, which shows that the equivalent continuous method can calculate the overall deformation after excavation of a large underground powerhouse in a jointed rock mass. Furthermore, the three-dimensional equivalent continuous numerical calculation of underground powerhouse excavation is carried out by using the equivalent mechanical parameters determined by the RVE and Hoek–Brown criterion. Compared with the actual measurement results of the multipoint displacement meter, the mean relative error of the calculation result based on the RVE is 12.37 %, and the mean relative error of the calculation result using the Hoek–Brown criterion is 20.37 %, indicating that the numerical calculation using the mechanical parameters of the RVE of the jointed rock mass as equivalent mechanical parameters can consider the size effect of the jointed rock mass and reduce the error of the numerical calculation. Our results are expected to provide guidance for evaluating the stability of an underground powerhouse.

对于地下电站围岩的稳定性分析,可靠的岩体力学参数和适当的分析方法非常重要。本文以吴越抽水蓄能电站地下电站为例,讨论了将节理岩体代表体积元(RVE)的力学参数作为等效力学参数,并采用等效连续性方法模拟大型地下电站在节理岩体中开挖的合理性。首先,建立了节理岩体的离散断裂网(DFN)和合成岩体(SRM)。通过数值试验,确定岩体的 RVE 尺寸为 23 m × 23 m × 23 m。RVE 的力学参数被用作岩体的等效力学参数。然后,采用等效连续法和非连续法对主电站开挖进行了二维数值计算。两种方法计算出的围岩变形平均相对误差为 8.24%,这表明等效连续法可以计算出节理岩体中大型地下发电站开挖后的整体变形。此外,利用 RVE 和 Hoek-Brown 准则确定的等效力学参数,对地下发电站开挖进行了三维等效连续数值计算。与多点位移计的实际测量结果相比,基于 RVE 的计算结果的平均相对误差为 12.37%,而使用 Hoek-Brown 准则的计算结果的平均相对误差为 20.37%,这表明使用节理岩体的 RVE 力学参数作为等效力学参数进行数值计算可以考虑节理岩体的尺寸效应,减少数值计算的误差。我们的结果有望为地下发电站的稳定性评估提供指导。
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引用次数: 0
Catastrophic failure mechanism of underground complexes under deep construction disturbance 深层施工扰动下地下建筑群的灾难性破坏机制
IF 6.7 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Pub Date : 2024-09-07 DOI: 10.1016/j.tust.2024.106059

The burgeoning demand for land resources in cities has spurred the development of intricate underground infrastructure networks. Therefore, evaluating the performance and stability of entire existing underground complexes in the event of construction-related disturbances becomes increasingly crucial for ensuring overall urban resilience. This paper adopts a coupled modeling technique of the Finite Element Method (FEM) and Smoothed Particle Hydrodynamics (SPH) for the analysis of catastrophic failure mechanisms in underground complexes, with a focus on disturbances due to nearby tunneling. Two-dimensional centrifuge model experiments were used to thoroughly calibrate the coupled FEM-SPH method, validating its accuracy and suitability for the simulation of soil–structure interaction problems. Subsequently, a full-scale integrated model of the underground complex and formation in a given area was established, including the subway network and highway system. Taking into account the longitudinal connections of the tunnel segments, the catastrophic coupling mechanisms related to construction disturbances in deep tunneling were investigated. The results indicate that collapsed soil caused by deep construction disturbances spreads through the gaps between the tunnels towards the ground, acting as a force-transmitting medium to correlate the deformations of the different structures. The response of the structures was evaluated using five different patterns of deformation, including tunnel settlement, dislocation, opening, rotation, and ovalization. In addition, the evolution of the performance of the underground complex during construction disturbances was analyzed using three types of indicators. Finally, the assessment of the catastrophic failure degree and the identification of vulnerable areas within the complex were carried out.

城市对土地资源的需求急剧增长,推动了错综复杂的地下基础设施网络的发展。因此,评估整个现有地下建筑群在与施工相关的干扰情况下的性能和稳定性,对于确保城市的整体抗灾能力变得越来越重要。本文采用有限元法(FEM)和平滑粒子流体力学(SPH)的耦合建模技术来分析地下综合体的灾难性破坏机制,重点关注附近隧道施工造成的扰动。利用二维离心机模型试验对 FEM-SPH 耦合方法进行了全面校准,验证了该方法的准确性和对土壤-结构相互作用问题模拟的适用性。随后,建立了特定区域地下综合体和地层的全尺寸综合模型,包括地铁网络和高速公路系统。考虑到隧道段的纵向连接,研究了与深层隧道施工扰动有关的灾难性耦合机制。结果表明,由深层施工扰动引起的塌方土通过隧道之间的缝隙向地面扩散,成为力传递介质,使不同结构的变形相互关联。采用五种不同的变形模式对结构的响应进行了评估,包括隧道沉降、错位、开口、旋转和椭圆化。此外,还利用三种指标分析了施工扰动期间地下建筑群性能的变化。最后,还对灾难性破坏程度进行了评估,并确定了综合体内的脆弱区域。
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引用次数: 0
Constructing underground pedestrian networks: A model based on the source-sink theory and a case study of Xinjiekou in Nanjing City, China 构建地下步行网络:基于源汇理论的模型和中国南京市新街口案例研究
IF 6.7 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Pub Date : 2024-09-07 DOI: 10.1016/j.tust.2024.106061

Underground pedestrian networks (UPNs), serving as a comprehensive approach for utilising urban underground spaces to address connectivity and spatial challenges, have undergone significant development in numerous major city centres. Well-designed UPNs are pivotal in developing compact cities, bolstering urban resilience, enhancing urban transportation systems, fostering urban renewal, and facilitating sustainable urban development. This study explores the construction methodology of UPNs by utilising the source-sink theory and relevant models. Using Xinjiekou District in Nanjing City as a case study, this study employs the minimum cumulative resistance model to simulate a UPN and conduct analysis of pedestrian flow clustering on the simulation results. The findings demonstrate that our proposed method effectively elucidates and predicts the connectivity of UPNs, enabling us to construct an optimal network with minimal cost. Moreover, the simulation network significantly enhances the optimisation of pedestrian flow distribution. Building upon these simulation results, the UPN in the study area is optimised by integrating real-world conditions and conducting degree centrality analysis. The findings are then utilised to propose policy recommendations for UPN layout planning in urban centres. This study serves as a valuable reference for underground space planning in the study area and provides insights for UPN construction in other urban centres.

地下步行网络(UPNs)是一种利用城市地下空间解决连通性和空间挑战的综合方法,在许多主要城市中心得到了长足发展。精心设计的地下步行网络在发展紧凑型城市、增强城市韧性、改善城市交通系统、促进城市更新和推动城市可持续发展方面发挥着关键作用。本研究利用源汇理论和相关模型,探讨了建设 UPN 的方法。以南京市新街口地区为例,采用最小累积阻力模型模拟 UPN,并对模拟结果进行人流集聚分析。研究结果表明,我们提出的方法有效地阐明并预测了 UPN 的连通性,使我们能够以最小的成本构建最优网络。此外,模拟网络还大大提高了人流分布的优化效果。在这些模拟结果的基础上,我们结合实际情况,对研究区域的 UPN 进行了优化,并进行了程度中心性分析。然后,利用研究结果为城市中心的 UPN 布局规划提出政策建议。这项研究为研究区域的地下空间规划提供了有价值的参考,并为其他城市中心的 UPN 建设提供了启示。
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引用次数: 0
期刊
Tunnelling and Underground Space Technology
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