電阻層析成像模塊

　　基于電阻率層析成像的三維旋噴灌注加固形態(tài)監(jiān)測

　　Research on electrical resistance tomography of Monitoring of 3D rotary jet grouting reinforcement morphology

　　背景介紹

　　Background

　　本案例利用電阻層析成像和三維打印技術(shù)對旋噴灌注樁的三維幾何形態(tài)進行物理模擬和實驗監(jiān)測。首先，通過使用三維打印技術(shù)對碳晶導(dǎo)電增強材料進行類旋噴樁的模型構(gòu)造，其次使用電阻層析成像系統(tǒng)對固化作用后的類旋噴樁進行重構(gòu)建模，利用粉末三維打印技術(shù)構(gòu)建小型加固試樣進行加固體幾何形態(tài)和力學(xué)特性研究。通過實驗研究，得到了室內(nèi)工況下旋噴灌注樁三維加固形態(tài)和加固力學(xué)特性的物理實驗數(shù)據(jù)，探索了電阻層析成像和三維打印技術(shù)在巖土加固研究中的應(yīng)用，為后續(xù)的三維加固形態(tài)數(shù)學(xué)建模和數(shù)值模擬分析提供了初步的驗證數(shù)據(jù)。

　　This case utilizes electrical resistance tomography and 3D printing technology to physically simulate and experimentally monitor the three-dimensional geometric shape of rotary sprinkler irrigation piles. Firstly, a three-dimensional printing technology was used to construct a model of carbon crystal conductive reinforcement material similar to rotary jet grouting piles. Secondly, a resistance tomography system was used to reconstruct and model the solidified rotary jet grouting piles. Finally, a small reinforced sample was constructed using powder three-dimensional printing technology to study the solid geometry and mechanical properties. Through experimental research, physical experimental data on the three-dimensional reinforcement morphology and mechanical characteristics of rotary jet grouting piles under indoor working conditions were obtained. The application of electrical resistance tomography and three-dimensional printing technology in geotechnical reinforcement research was explored, providing preliminary validation data for subsequent mathematical modeling and numerical simulation analysis of three-dimensional reinforcement morphology.

　　關(guān)鍵技術(shù)1：碳精粉混合導(dǎo)電材料制備

　　Preparation of carbon fine powder mixed conductive materials

　　關(guān)鍵技術(shù)2：三維旋噴灌注加固體圖像重構(gòu)

　　3D rotary jet grouting with solid image reconstruction

　　關(guān)鍵技術(shù)3：三維粉末打印的小型加固形態(tài)和力學(xué)性能研究

　　Research on small reinforcement morphology and mechanical properties of 3D powder printing