复合绝缘子内部缺陷超声相控阵柔性耦合检测

为解决小管径复合绝缘子内部缺陷在线检测中超声探头与绝缘子耦合困难的问题,提出了一种基于水囊柔性耦合的复合绝缘子超声相控阵检测方法。该方法利用材质与绝缘子护套声学特性接近的硅橡胶水囊实现探头与绝缘子的良好耦合。并分别进行了护套和芯棒的缺陷检测实验。实验结果表明:针对护套,水囊耦合法与传统水浸法均能够检测到直径1.0mm的缺陷,且二者相控阵扫描图像一致;针对芯棒,水囊耦合法能够检测到直径2.0 mm的多处缺陷,缺陷识别率高。实验验证了水囊耦合法应用于超声相控阵复合绝缘子检测的可行性,为输电线路复合绝缘子内部缺陷在线检测奠定了基础。

长源距随钻定向电磁波测井仪器频率和源距选择方法

长源距远探测是随钻定向电磁波测井的发展趋势。如何在提高探测深度的同时拓宽地层探测范围是仪器设计需考虑的重要问题。本文基于磁流源并矢格林函数法研究了测井仪器接收线圈感应电动势对地层电阻率的敏感性,提出频率和源距的选择方法。在此基础上研究仪器界面距离和电阻率对比度对接收线圈感应电动势旋转变化特性的影响。搭建长源距定向测井缩比模型实验平台,开展不同电阻率对比度时接收信号旋转变化特性实验研究,验证了频率和源距选择方法的正确性。该方法可为针对不同地层合理选择线圈系参数并拓宽地层电阻率探测范围提供依据。

长源距定向电磁波测井仪器探测深度影响因素分析

探测深度是衡量测井仪器探测性能的核心指标。探测深度受源距、频率、地层电阻率和仪器对微弱信号的分辨能力等多种因素的影响。基于并矢格林函数理论,研究仪器探测深度与源距和地层电阻率的关系。根据仪器响应对地层电阻率的敏感性,提出将地层划分为双向敏感区、单向敏感区和不敏感区的方法,分析不同敏感区探测深度的变化规律。在双向敏感区,电阻率对比度越大探测深度越大;在单向敏感区,探测深度只随着敏感区电阻率变化;在同一不敏感区,即使地层电阻率对比度很大,探测深度很小甚至为零。搭建长源距定向测井缩比模型实验平台,研究不同电阻率对比度时仪器的响应特性,验证了不同敏感区探测深度变化规律的正确性。研究结果可为测井仪器线圈系设计提供理论依据。

Technique for Advanced Electrochemical Oxidation Treatment of Nanofiltration Concentrate of Landfill Leachate

Landfill leachate treated with combined process of ＂pretreatment ＋biological treatment ＋advanced treatment （NF）＂ to produce nanofiltration concentrate, which bio-chemical ratio （B/C） is less than 0.1 and CODer concentration is 2 000-2 500 mg/L, high salt content. Which cannot be discharged under existing environ- mental standards. According to analysis based on electrochemical advanced oxidation mechanism, a two-step electrochemical tech- nique was recommended. In the first step, a pulse electrochemical technique was adopted. With Fe as consumption electrode and current density of 10 mA/cm2, the pollutants were removed by means of Fenton reaction, electroflotation and electrocoagulation. In the second step, a double function electrode was used to per- form electrocatalytic oxidation by means of titanium metallic oxi- dates. In the condition that current density being 12.5 mA/cm2, the pollutants were further removed by oxidation and electrolytic deposition. Result shows that the removing rate of CODer, NH3-N and CI were 70%-85%, 90% and 25%, respectively; average value of B/C ratio increased from 0.09 to 0.38 and conductivity reduced by 10%.