组合钢管混凝土式防屈曲支撑

由于河北省图书馆加固改造工程的实际需要,开发出了一种新型组合钢管混凝土式防屈曲支撑。该新型支撑解决了全钢型防屈曲支撑在大长度时难以满足稳定性的问题,而且比起传统钢管混凝土约束的防屈曲支撑,无需考虑内芯与混凝土之间的粘结力问题,加工过程简便、施工速度快,且质量容易控制。现已对此类新型支撑完成了短试件和足尺试件的拟静力滞回性能试验,试验结果表明,新型支撑的滞回曲线饱满稳定,整体稳定性和局部稳定性较好,满足工程要求。     

煤层瓦斯含量测定定点取样方法研究进展

基于文献调研及前期研究,分析了目前煤矿井下煤层瓦斯含量直接测定时所采用定点取样方法及其弊端,阐述了学者们提出的改进型定点取样方法,并对煤层瓦斯含量测定定点取样方法的研究进行了展望,指出:①取样过程瓦斯损失量小、取样时升温低、机械复杂度低是基于煤芯管法定点取样方法的发展方向;②开展煤储层条件下的瓦斯运移规律研究,建立并完善各种基于煤芯管法的定点取样方法的瓦斯损失量模型;③适用于松软煤层的定点取样方法的研发亟待开展;④基于负压气力输送理论的定点取样方法是定点取样方法研究的趋势,动态颗粒煤变负压瓦斯解吸规律是建立对应瓦斯损失量模型的基础研究。     

油池火作用下钢管混凝土柱温度分布研究

在开敞空间条件下利用油池火模拟不同的火灾场景,对火源燃烧阶段和燃烧结束后钢管混凝土柱的温度变化进行研究。测量了燃料质量变化和钢管混凝土柱的温度分布等参数,分析不同火灾场景下钢管混凝土柱轴向、横截面的温度变化,并以实验工况HS3为例进行深入分析,同时分析了火源的燃烧时间、热释放速率对钢管混凝土柱温度场分布的影响。研究结果表明,钢管混凝土柱纵向温度分布与横向温度分布一样都存在明显的温度梯度,其表面钢管温度变化受火场热释放速率影响较大,而内部混凝土的温度变化则主要受火场持续时间的影响。     

陶瓷纤维滤管在烟气净化一体化技术中的应用

在对国内外现有的一体化烟气处理工艺系统梳理的基础上,重点分析了基于陶瓷纤维滤管的烟气净化一体化技术,对其技术原理、应用特性、应用现状进行了分析总结,并以江苏某垃圾焚烧发电厂中试示范项目为例进行验证.结果表明,NOx、SO2、HCl、颗粒物、二噁英类去除效率分别为97.6％、84.1％、74.8％、>99.9％、99.9...     

弯管与盲通管冲蚀磨损对比分析研究

为了研究石油管道流向急剧改变处的冲蚀磨损问题,采用DPM模型,通过改变入口流速、颗粒质量流速、颗粒直径,对90°弯管与盲通管的流场分布及冲蚀情况进行数值模拟。结果表明:弯管与盲通管最大冲蚀速率随入口流速的增大呈指数增长,随颗粒质量流速的增大呈线性增长;在50~100 μm粒径范围内,最大冲蚀速率随粒径的增加逐渐减小,在100~300 μm粒径范围内,随粒径的增加而增大;在入口流速、颗粒质量流速、颗粒直径相同的条件下,弯管最大冲蚀速率明显高于盲通管最大冲蚀速率,盲通管的耐蚀性更强;由于流体在盲通管产生涡旋现象,增加了颗粒能量的耗散,从而减小了进入下游管线颗粒的速率,使得颗粒更易积存于盲通段形成堆积层,减小了下游管段冲蚀速率。     

Small-scale physical explosions in shock tubes in comparison with condensed high explosive detonations

A series of small-scale experiments involving physical explosions in a 1.6 l pressure vessel was carried out. Explosions were initiated by spontaneous rupture of an aluminium membrane on one side of the vessel at a pressure in the range 1–1.2 MPa. The pressure waves released were measured at different distances along two separate shock tubes, one 10 m long and 200 mm in diameter (closed at one end by the high pressure vessel) and the other 15 m long and 100 mm in diameter.TNT equivalency was used for predicting the blast wave characteristics after vessel rupture. TNT equivalency was used because equations for prediction of peak pressure and impulse of the blast wave in 1-D geometry after detonations of condensed explosives are known. Some experiments with an equivalent amount of real explosive were carried out for comparison with the theoretical and experimental data obtained. The applicability of the TNT equivalency method presented for calculations of maximum pressure and shock wave impulse generated after rupture of the pressure vessel in 1-D geometry is discussed.     

电站锅炉水冷壁和过热器爆管分析

采用宏观形貌分析、化学成分分析、金相显微组织分析、材料力学性能测试、SEM微观形貌分析等手段,对某电站锅炉水冷壁管和过热器管破裂进行了分析。结果表明,热（硫）腐蚀导致的过热器管局部穿孔破裂,以及泄漏产生的高温水汽流对水冷壁管的,中刷磨损是爆管的主要原因,过热器管补焊点的再次泄漏是本次事故的直接原因。     

Experimental analysis of thermal performance of evacuated tube and flat-plate solar air collectors at different air flow rates

The thermal performances of an evacuated tube collector (ETC) and flat-plate solar air collector (FPC) are experimentally investigated at different air flow rates. To investigate the performance of the ETC and FPC, experimental set-ups were fabricated. Air was used as a working fluid and tested at the same climatic conditions. The ETC had 15 evacuated tubes with a surface area of 1.66 m². The experimental set-up consisted of a header with a hollow pipe (square pipe) in the centre through which the air flowed. The flat-plate collector had a surface area of 1.35 m². The FPC had a black painted absorber sheet which divides the collector into two sections. The air flowed through the upper and the lower sections parallel to the collector to minimize the overall heat loss. The temperature of the outlet air depends on several factors along with the airflow rate and the intensity of the solar radiation. It was found that during the day at high flow rates, the efficiency of the ETC varies from 0.12 to 0.5, and for the flat plate it was from 0.29 to 0.68. The maximum temperature of the air was 56.7°C for the ETC and 25.7°C for the FPC.     

爆炸形成过程中火焰加速的试验研究

为预防和控制工业爆炸事故,并为脉冲爆轰发动机的研究提供理论指导,分析火焰加速导致的燃烧转爆轰过程的影响因素。采用爆轰管探讨障碍物的阻塞比、混合物的组成、初始压力和点火能等4个因素对爆炸性气体火焰速度和爆轰压力的影响规律。试验结果表明:障碍物的存在能大大提高火焰速度和爆轰压力;爆轰压力随管内障碍物阻塞比的增大先变大后减小,并在阻塞比为0.498,燃料种类为天然气,化学当量比为1时达到最大;爆轰压力还随混合气体初始压力的增大和点火能的提高而增大。选择适宜的条件可大大提高火焰加速速率,促进燃烧向爆轰过程转变。     

Numerical simulation of propane detonation in medium and large scale geometries

A modelling strategy has been developed for consequence analysis of medium and large scale gaseous detonation. The model is based on the solution of Euler equations with one-step chemistry. The Van Leer flux limited method which is a total variation diminishing scheme is used for shock capturing. Preliminary calculations were firstly conducted for small domains with fine grids which resolve the wave, relatively coarse grids which have less than 10 grids across the wave and coarse grids in which the minimum grid size is larger than the wave thickness to ensure that the reaction scheme has been properly tuned to capture the correct detonation pressure, temperature and velocity in the resolutions used in the different cases. The model was firstly tested against a medium scale detonation test in a shock tube with U-bends. Reasonably good agreement is achieved on detonation pressure and mean shock wave velocities at different measuring segments of the tube. Following the validation, the detonation of a hypothetical planar propane-air cloud is simulated. The predictions uncovered some interesting features of such large scale detonation phenomena which are of significance in the safety context, especially for accidental investigations. The findings from the present analysis are in line with the forensic evidence on damages in some historic accidents and challenges previous analysis of a major accident in which forensic evidence suggested localised detonation but was considered as the consequence of fire storms by the investigation team.