公开(公告)号：US20220318462A1

公开(公告)日：2022-10-06

申请号：US17299100

申请日：2020-10-23

申请人： SHANDONG UNIVERSITY

发明人： Shucai LI ,  Zongqing ZHOU ,  Liping LI ,  Weimin YANG ,  Chunjin LIN ,  Shaoshuai SHI ,  Chenglu GAO ,  Chengshun SHANG ,  Yang GENG ,  Songsong BAI

IPC分类号： G06F30/25

摘要： A discrete element method contact model building method includes: selecting a filling body in a disaster-causing structure to obtain a change rule of cumulative loss of the filling body ; performing test simulation, and determining a relation function of each group of corresponding mesoscopic mechanical parameters in each time period and mesoscopic parameters of a DEM contact model representing a change rule of macroscopical parameters of the filling body; embedding each mesoscopic parameter relation function into an existing particle contact model, performing test simulation, and updating a fracture failure criterion of the contact model according to a corresponding relation of macro-mesoscopic strength during model failure; and based on a seepage failure indoor test, building a seepage failure discrete element calculation model, and simulating the seepage failure process of a rock and soil mass by using the obtained particle contact model and the fracture criterion of the particle contact model.

公开(公告)号：US20220284155A1

公开(公告)日：2022-09-08

申请号：US17630231

申请日：2020-10-22

申请人： SHANDONG UNIVERSITY

发明人： Shucai LI ,  Zongqing ZHOU ,  Liping LI ,  Chunjin LIN ,  Shaoshuai SHI ,  Chenglu GAO ,  Cheche WEI ,  Chengshun SHANG ,  Songsong BAI

IPC分类号： G06F30/23 ,  G06F30/13

摘要： A rock mass engineering cross-scale simulation calculation method based on REV all-region coverage, including establishing a rock mass engineering scale calculation model of particles and joints, and providing the model with particle material parameters and contact parameters; performing model region division dividing the model into multiple finite elements, and performing all-region coverage and mesh division using the finite elements, wherein a volume of the finite element is equal to a representative elementary volume of a REV model; and applying boundary conditions, calculating force and motion information of finite element nodes using a continuous medium method, obtaining a failed finite element according to the node force and motion information, and calculating motion information of particles of the REV model in the failed finite element using a discontinuous medium method. According to the calculation method, the calculation efficiency is improved, and the accuracy of calculation results is ensured.

公开(公告)号：US20220284152A1

公开(公告)日：2022-09-08

申请号：US17630422

申请日：2020-10-22

申请人： SHANDONG UNIVERSITY

发明人： Shucai LI ,  Liping LI ,  Zongqing ZHOU ,  Chenglu GAO ,  Shaoshuai SHI ,  Shuai CHENG ,  Zhuohui LI ,  Daosheng ZHANG ,  Wenfeng TU ,  Meixia WANG

IPC分类号： G06F30/20

摘要： A peridynamics method and system for tunnel rock mass failure water inrush catastrophe simulation. A calculation model is discretized into material points, and a virtual boundary layers is set on an outer side of a boundary of the calculation model as an object to which boundary conditions are applied; a size of a horizon of the material points is selected to form a neighborhood matrix; a crustal stress is made equivalent to a stress boundary condition of the calculation model, a karst cave water pressure is made equivalent to a normal pressure, and a displacement constraint and tunnel support are converted into a displacement boundary condition; a speed and a displacement of the material point are solved, and local damage situations are recorded; and a tunnel construction process is simulated by material point dormancy after initial balance calculation is stable.

公开(公告)号：US20190383714A1

公开(公告)日：2019-12-19

申请号：US16314460

申请日：2017-09-28

申请人： SHANDONG UNIVERSITY

发明人： Shucai LI ,  Weimin YANG ,  Zongqing ZHOU ,  Liping LI ,  Shaoshuai SHI ,  Meixia WANG ,  Shuai CHENG ,  Xuguang CHEN ,  Chenglu GAO ,  Cong LIU

IPC分类号： G01N3/02 ,  G01N3/12

摘要： Fully automatic true triaxial tunnel and underground project model test system, including a triaxial loading device for loading model test piece, automatic data collection and analysis device, power system and control system; triaxial loading device includes test bench, vertical loading system, horizontal front and back, and left and right loading systems, and the vertical, horizontal front and back, and left and right loading systems apply three-way pressure to model test body; test bench functions for supporting, fixing, and providing counter-force; automatic data collection and analysis device includes micro optical fiber sensor embedded in model test piece, optical fiber monitoring system, micro pressure box and strain brick, and can collect multi-field information.