盾构渣土环保处理系统流体技术研究及应用

盾构施工会产生大量渣土,采用传统填埋消纳方式处理盾构渣土会造成土地资源浪费和环境污染,因此盾构渣土必须采用分离、脱水、回收利用等环保方式进行处理。若处理流程中的各个子系统、各设备之间没有进行合理的参数匹配,就会造成水池或管路淤积、设备损坏、旋流器失压失效等问题,系统无法长时间稳定工作。为解决上述问题,依托深圳地铁14号线某施工区间的盾构渣土环保处理流程,分析其中的流体技术,提出通过理论和经验计算进行渣土环保处理系统流体匹配的方法,并将此方法运用到该项目的设计、选型中。运行情况表明,运用此方法匹配的流体系统可长期稳定运行,渣土分离、脱水效果好,流体总体达到平衡,实现了水的循环利用。本文提出的流体匹配方法不只适用于本流程,同样适用于大部分渣土处理流程,不同项目可根据处理量和渣土的具体组成,参考本方法进行匹配计算。

三元约束油气检测技术在油气勘探中的应用

莱北油田新近系明下段油气勘探是近年来渤海地区勘探的热点与储量增长点。该地区油水关系复杂,同时常规油气检测方法受砂体厚度、物性及地层结构等其他非流体因素干扰较大,导致常规方法钻前油气预测多解性强,严重制约了该区的集束评价。为此,文中首次引入能量衰减识别因子、隐性油气识别因子与构造流体匹配识别因子,并将三者有机融合,建立了基于能量衰减的三元约束流体(油气)检测新方法。该方法首先从能量衰减机理与正演模拟出发,得到地震波穿过含不同流体的砂体后的能量衰减识别因子,然后对油气层的振幅进行分解,得到可以表征油气的隐性油气识别因子,最后充分考虑构造对流体的控制作用,引入构造流体匹配识别因子;通过引入3个对油气敏感的定量评价因子,并将三者融合建立三元约束定量化流体检测模板,实现对油气水层的精准预测。该方法具有快速、准确、高效的优点,有效解决了油气水层振幅能量的混叠难题,业已在莱北油田进行广泛应用,并获得了良好的勘探成效。

DC Characteristics of Lattice-Matched InAlN/AlN/GaN High Electron Mobility Transistors

Lattice-matched InAlN/AlN/GaN high electron mobility transistors (HEMTs) grown on sapphire substrate by using low-pressure metallorganic chemical vapor deposition were prepared, and the comprehensive DC characteristics were implemented by Keithley 4200 Semiconductor Characterization System. The experimental results indicated that a maximum drain current over 400 mA/mm and a peak external transconductance of 215 mS/mm can be achieved in the initial HEMTs. However, after the devices endured a 10-h thermal aging in furnace under nitrogen condition at 300 ℃, the maximum reduction of saturation drain current and external transconductance at high gate-source voltage and drain-source voltage were 30% and 35%, respectively. Additionally, an increased drain-source leakage current was observed at three-terminal off-state. It was inferred that the degradation was mainly related to electron-trapping defects in the InAlN barrier layer.