The application of a large-scale slurry-balance shield machine in supe的简体中文翻译

The application of a large-scale sl

The application of a large-scale slurry-balance shield machine in super-large tunnel excavation (diameter >14 m) is much more difficult and risky than the common shield tunneling. The control of shield machine becomes a complex and difficult problem under frequently encountered unforeseen geological conditions. The operators of shield machine need to recognize the influential parameters for excavation stability, and then primarily adjust these influential parameters which can be controlled in shield machine tunneling. Aiming to find out the influential parameters for excavation stability, this study proposes a framework of global sensitivity analysis (GSA) by (i) employing three different meta-models namely polynomial chaos expansion (PCE), radial basis function (RBF), and support vector machine (SVM) methods to mimic the mapping relation between input and output parameters, and (ii) adopting three kinds of GSA methods namely Morris elementary effects, Sobol method, Expand Fourier amplitude sensitivity test (EFAST) algorithm to classify the parameters as important or unimportant (insensitive). The results show that the synchronous grouting pressure, advancing speed, and penetration are influential parameters to bubble chamber pressure, whereas the cutter rotation speed, cutter torque, penetration, and actual volume excavation are influential parameters to deviation angle. Here, we pay close attention to the most influential parameters that must be prioritized for parameter control, which can help the administrators optimize their management scheme of influential parameters during tunnel excavation. The follow-up research can focus on how to develop and explore additional particular details about the GSA method or some other data mining technologies for optimizing the management scheme of shield tunneling.
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结果 (简体中文) 1: [复制]
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大型泥水平衡盾构机在超大型隧道开挖(直径> 14 m)中的应用比普通盾构隧道施工更加困难和危险。在经常遇到的不可预见的地质条件下,盾构机的控制成为一个复杂而困难的问题。盾构机的操作人员需要识别影响挖掘稳定性的参数,然后首先调整这些可以在盾构机隧道中控制的参数。为了找出影响挖掘稳定性的参数,本研究提出了一种全球敏感性分析的框架,方法是:(i)采用三种不同的元模型,即多项式混沌扩展(PCE),径向基函数(RBF),和支持向量机(SVM)方法来模拟输入和输出参数之间的映射关系,以及(ii)采用三种GSA方法(即莫里斯基本效应,Sobol方法,扩展傅立叶振幅敏感度测试(EFAST)算法)对参数进行分类一样重要或不重要(不敏感)。结果表明,同步注浆压力,行进速度和穿透力是影响气泡室压力的参数,而切刀转速,切刀扭矩,穿透力和实际开挖量是影响偏角的参数。在此,我们密切关注必须优先考虑的最有影响力的参数控制参数,这可以帮助管理员在隧道开挖期间优化其有影响力参数的管理方案。
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结果 (简体中文) 2:[复制]
复制成功!
The application of a large-scale slurry-balance shield machine in super-large tunnel excavation (diameter >14 m) is much more difficult and risky than the common shield tunneling. The control of shield machine becomes a complex and difficult problem under frequently encountered unforeseen geological conditions. The operators of shield machine need to recognize the influential parameters for excavation stability, and then primarily adjust these influential parameters which can be controlled in shield machine tunneling. Aiming to find out the influential parameters for excavation stability, this study proposes a framework of global sensitivity analysis (GSA) by (i) employing three different meta-models namely polynomial chaos expansion (PCE), radial basis function (RBF), and support vector machine (SVM) methods to mimic the mapping relation between input and output parameters, and (ii) adopting three kinds of GSA methods namely Morris elementary effects, Sobol method, Expand Fourier amplitude sensitivity test (EFAST) algorithm to classify the parameters as important or unimportant (insensitive). The results show that the synchronous grouting pressure, advancing speed, and penetration are influential parameters to bubble chamber pressure, whereas the cutter rotation speed, cutter torque, penetration, and actual volume excavation are influential parameters to deviation angle. Here, we pay close attention to the most influential parameters that must be prioritized for parameter control, which can help the administrators optimize their management scheme of influential parameters during tunnel excavation. The follow-up research can focus on how to develop and explore additional particular details about the GSA method or some other data mining technologies for optimizing the management scheme of shield tunneling.
正在翻译中..
结果 (简体中文) 3:[复制]
复制成功!
大型泥水平衡盾构机在超大型(直径大于14 m)隧道开挖中的应用,比一般盾构法施工难度大、风险大。盾构机的控制在经常遇到的不可预见的地质条件下成为一个复杂而困难的问题。盾构机作业人员需要识别影响开挖稳定性的参数,并对这些参数进行初步调整,使之在盾构机掘进过程中得到控制。为了找出影响基坑稳定性的参数,本文提出了一个全局灵敏度分析框架,该框架采用了三种不同的元模型,即多项式混沌展开(PCE)、径向基函数(RBF),以及支持向量机(SVM)方法来模拟输入输出参数之间的映射关系,以及(ii)采用三种GSA方法,即Morris基本效应法、Sobol方法、扩展傅立叶振幅灵敏度试验(EFAST)算法来对参数进行重要或不重要(不敏感)的分类。结果表明:同步注浆压力、推进速度、贯入度是影响气泡室压力的主要参数,而切刀转速、切刀扭矩、贯入度和实际体积开挖量是影响气泡室压力的主要参数。在这里,我们密切关注参数控制中必须优先考虑的最有影响的参数,这有助于管理者优化隧道开挖过程中影响参数的管理方案。后续的研究可以集中在如何开发和探索GSA方法或其他一些数据挖掘技术的细节,以优化盾构隧道的管理方案。<br>
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