烟气循环流化床（CFB-FGD）干法脱硫优化调整

本文分析了烟气循环流化床工艺的运行调节原理,针对电厂自身的特点,对吸收塔进出口烟温差及床层压降参数进行调整,提高了烟气循环流化床系统运行的经济性.最后根据此实践提出了系统运行中优化调整的可行性.     

Methods for more accurate determination of explosion severity parameters

Accurate determination of explosion severity parameters (p_max, (dp/dt)_max, and K_St) is essential for dust explosion assessment, identification of mitigation strategy, and design of mitigation measure of proper capacity. The explosion severity parameters are determined according to standard methodology however variety of dust handled and operation circumstances may create practical challenge on the optimal test method and subsequent data interpretation. Two methods are presented: a statistical method, which considers all test results in determination of explosion severity parameters and a method that corrects the results for differences of turbulence intensity. The statistical method also calculates experimental error (uncertainty) that characterises the experimental spread, allows comparison to other dust samples and may define quality determination threshold. The correction method allows to reduce discrepancies between results from 1 m³ vessel and 20-l sphere caused by difference in the turbulence intensity level. Additionally new experimental test method for difficult to inject samples together with its analysis is described. Such method is a versatile tool for explosion interpretation in test cases where different dispersion nozzle is used (various turbulence level in the test chamber) because of either specific test requirements or being “difficult dust sample”.     

Experimental investigation of gas explosion in single vessel and connected vessels

Gas explosion in connected vessels usually leads to high pressure and high rate of pressure increase which the vessels and pipes can not tolerate. Severe human casualties and property losses may occur due to the variation characteristics of gas explosion pressure in connected vessels. To determine gas explosion strength, an experimental testing system for methane and air mixture explosion in a single vessel, in a single vessel connected a pipe and in connected vessels has been set up. The experiment apparatus consisted of two spherical vessels of 350 mm and 600 mm in diameter, three connecting pipes of 89 mm in diameter and 6 m in length. First, the results of gas explosion pressure in a single vessel and connected vessels were compared and analyzed. And then the development of gas explosion, its changing characteristics and relevant influencing factors were analyzed. When gas explosion occurs in a single vessel, the maximum explosion pressure and pressure growth rate with ignition at the center of a spherical vessel are higher than those with ignition on the inner-wall of the vessel. In conclusion, besides ignition source on the inner wall, the ignition source at the center of the vessels must be avoided to reduce the damage level. When the gas mixture is ignited in the large vessel, the maximum explosion pressure and explosion pressure rising rate in the small vessel raise. And the maximum explosion pressure and pressure rising rate in connected vessels are higher than those in the single containment vessel. So whenever possible, some isolation techniques, such as fast-acting valves, rotary valves, etc., might be applied to reduce explosion strength in the integrated system. However, when the gas mixture is ignited in the small vessel, the maximum explosion pressures in the large vessel and in the small vessel both decrease. Moreover, the explosion pressure is lower than that in the single vessel. When gas explosion happens in a single vessel connected to a pipe, the maximum explosion pressure occurs at the end of the pipe if the gas mixture is ignited in the spherical vessel. Therefore, installing a pipe into the system can reduce the maximum explosion pressure, but it also causes the explosion pressure growth rate to increase.     

金昌市PM2.5及PM10短期暴露对成人血压水平的影响

为探索西北地区颗粒物(PM)短期暴露对人群血压(BP)水平的影响,基于金昌队列研究平台,收集甘肃省金昌市2011~2017年颗粒物污染数据及队列人群血压测量数据,在调整相关混杂因素基础上,采用线性混合效应模型分析PM_2.5和PM₁₀短期暴露对收缩压(SBP)、舒张压(DBP)、平均动脉压(MAP)、脉压(PP)和Mid-BP (SBP和DBP的均值)的影响.结果显示,随着PM_2.5浓度的增加,人群SBP,MAP,PP和Mid-BP均呈上升趋势,该效应值分别在累积滞后05,03,07和05d最大.随着PM₁₀浓度的增加,5种BP指标也均呈上升趋势,效应最大值均出现在累积滞后07d.PM_2.5和PM₁₀对BP产生的影响分别在吸烟和男性人群中更为显著.此外,沙尘天气和气态污染物(SO₂和NO₂)对PM-BP效应存在一定的修饰作用.因此,在该队列人群中,PM_2.5和PM₁₀短期暴露对人群血压具有一定影响,吸烟者和男性人群可能是颗粒物影响血压效应的易感人群.     

反应堆压力容器保温层辐射屏蔽组件传热计算分析及屏蔽材料试验研究

目的 确保华龙一号HPR1000反应堆压力容器保温层辐射屏蔽组件在运行工况下的可靠性、安全性以及能够有效执行其功能。方法 采用基于传热理论结合经验公式的理论计算方法,以及流固耦合的有限元仿真分析,对辐射屏蔽组件的运行温度进行计算。针对屏蔽材料在受热状态下的性质变化,进行一系列的热态性质试验。结果 理论计算方法得到的结果为163.36~168.74 ℃,有限元仿真分析得到的结果为236.85~266.85 ℃,两者偏差约100 ℃。对造成该种差异的原因进行了分析,发现仿真分析方法得到的结果的置信度更高。屏蔽材料在受热状态下,其体积膨胀率可达到38.82%,而当屏蔽材料受热超过其温度限值204 ℃后,将出现明显的粉化等物理状态恶化的趋势。结论 流固耦合的有限元仿真分析方法更适用于辐射屏蔽组件的传热过程计算,同时获取了屏蔽材料物理性状受热变化趋势,对屏蔽组件的选材及结构设计具有指导意义。     

高海拔矿井掘进工作面局部增压的空气幕调控仿真研究

矿井环境一直是制约矿井地下安全生产的重要因素之一,尤其是在高海拔地域,由于空气的各项参数都与海拔高度相关,高海拔地区矿井在通风方面要比平原矿井有更多特殊要求。为解决高海拔地区矿井掘进工作面存在的低压缺氧问题,在对高海拔地区低压环境特性分析及传统矿用空气幕理论分析的基础上,根据增能增阻设计提出了多功能矿用空气幕联合增压模型,该模型在巷道两端分别布置引射型和增阻型矿用空气幕,以达到增压进而间接提高工作场所含氧量的效果。以青海省某金矿3 850 m中段开拓巷道掘进作业面为背景,借助有限元仿真软件Fluent对构建的开拓巷道的三维立体模型进行数值模拟。模拟结果与现场实测结果基本相符,结果表明:采用基于空气幕的增压增氧调控技术可使开拓巷道掘进作业面绝对气压由63 835 Pa增加至68 273 Pa,氧分压从12 040 Pa提高至14 213 Pa,达到海拔3 000 m的水平,可明显改善通风效果和通风质量;同时,随掘进作业面压力提高,采空区有害气体的逸出也得到有效抑制。该调控方法可以克服传统风流调控设施存在的布置困难、影响通行的问题,为提高高海拔地区井下压力及含氧量提供了新的思路。     

高压气层地层压力监测方法在YB122井的应用

YB122井录井人员从收集区域及邻井资料等基础地质工作开始,通过随钻地层跟踪分析,准确判断实钻地层层位,依据钻时参数变化、钻井液液面波动、池面上涨、气测异常等常规技术方法成功地监测到地层压力异常并采取应对措施,为该井顺利钻进提供了依据,对相似地层的地层压力监测工作有一定借鉴意义。     

改进的RBI技术在海上平台压力容器中的应用

海上平台压力容器检验周期的计算方法通常会产生过少或过度检验的问题,确定合理的检验周期对平衡压力容器的安全操作和检验成本具有重大意义。采用改进的RBI技术,对2种泄漏类型的压力容器系统分别设定不同的可接受风险,并将渐变模型引入压力容器检验周期计算方法中,计算了某海上生产平台上的51台压力容器的检验周期。结果表明,共有22个压力容器部位的检验周期得到调整,验证了改进的方法可以使检验周期数值更真实合理地反映设备风险,但对腐蚀率较小的损伤机理,采用渐变模型改进容器部位的检验周期效果不明显。     

四川省农业生产环境压力分析

研究主要采用产排污系数法,分析了2012年四川省农业投入品使用量及残留量,以及主要农业残留物产量,以咨环境管理参考。结果发现,四川全省化肥施用强度、农药使用强度和农用塑料薄膜残留量较大,化肥施用强度超标;年末作物秸秆产量3504.2万吨,焚烧(焚烧比20%)排放的细颗粒物质和总悬浮颗粒物超过4.0万吨;主要粪便污染物是COD与总氮,粪肥年施氮量及总磷均超过还田限值。农业稳定增产条件下,农业环境压力将持续增加。     

静电放电参数随电极移动速度和空气压强变化的特性分析

在小间隙静电放电(ESD)中,电极移动速度和气体压强会对测量放电参数出现的低重复离散特性产生影响。基于自主研发的新型测试系统,完成气体压强变化和向放电靶移动电极放电相关参数的测量。静电放电模拟器移动距离控制范围在10cm-40cm。在间隙气体压强变化和放电枪以不同速度向靶移动放电的两种情况下,放电电流峰值和波形产生了显著的差异,证明了电极移动速度和空气压强都对放电参数产生显著影响。本文对放电参数受电极移动速度和气体压强变化而出现显著差异的可能机制进行了初步分析。