微磁场条件下pH冲击对微氧活性污泥表面性质的影响

研究了微磁场条件下pH冲击对处理低负荷葡萄糖废水的微氧活性污泥表面性质的影响。在pH=6.0和9.0的条件下对添加磁粉和无磁粉反应器微氧活性污泥进行15 d的冲击,而后调整pH=7.5进行5 d的恢复实验。对pH冲击下污泥絮凝能力FA、疏水性RH和表面电荷SC的变化情况进行考察,结果表明,有磁粉反应器的各项指标均优于无磁粉反应器。经过5 d的恢复实验,添加磁粉反应器污泥的各指标均能恢复到接近初始值,而无磁粉反应器污泥难以恢复到接近初始值。     

近10 a武汉市城市热岛效应演变及其#br# 与土地利用变化的关系

城市化进程的加快，农村人口大量涌入城市，城市布局及局部气候改变等因素使得城市热岛效应问题日益突出，已成为当前城市环境研究热点之一。以武汉市为例，应用遥感技术与地理信息系统技术，选取2004~2015年5个时相Landsat系列影像数据，利用单窗算法反演地表温度，并以此为基础进行热岛强度分级，获取了近10 a武汉市城市热岛效应变化结果，并分析了武汉市11个辖区城市热岛效应动态变化特征及热岛效应与土地利用变化的关系。研究结果表明：（1）自2007年后，武汉市老城区热岛面积持续减少，而新城区热岛面积则持续增加，呈现出以老城区为中心向新城区扩张的趋势，至2015年，新老城区热岛面积仅相差20.74 km2；（2）东西湖区、蔡甸区、江夏区与洪山区是近些年城市热岛面积增长较为显著的辖区，其中江夏区的热岛面积年际变化最大，最高值达95.42 km2；（3）城市热岛效应与土地利用类型的面积年际平均值拟合关系显示，2004~2015年，城市热岛效应与建筑用地的R2值最大，为0.681 2，建筑用地面积的增加是城市热岛强度面积扩张的重要影响因素。     

The effect of greenhouse vegetation coverage and area on the performance of an earth-to-air heat exchanger for heating and cooling modes

The underground temperature at a depth of about 3–4 m is almost constant all the year round. In summer, the underground temperature is lower than the ambient temperature, but in winter it is vice versa. This potentiality is considered for greenhouse cooling and heating by using an earth-to-air heat exchanger (EAHE). This paper considers the effects of two parameters as independent variables including the area of greenhouse and the percentage of vegetation coverage inside the greenhouse on the performance of an EAHE system during both cooling and heating modes. The inside temperature, the thermal energy exchange and the coefficient of performance (COP) of the system were considered as dependent variables. The results showed that both greenhouse area and the percentage of vegetation coverage inside the greenhouse had significant effects on the performance of the EAHE system during both cooling and heating modes. However, the COP of the EAHE system was higher in the cooling mode (4.32) than during the heating mode (1.01). The percentage of vegetation coverage negatively affected the performance of the EAHE system in the cooling mode. However, the performance of the EAHE system improved with the increase in the percentage of vegetation coverage during the heating mode.     

Experimental investigation of a solar water distillation-cum-drying unit

In this communication, a new design of solar-energy-based water distillation cum drying unit with parabolic reflector has been designed, fabricated, and tested. Bitter gourd and potato slices are chosen as a drying commodity. Thermal performance of the developed system has been evaluated based on the experimental results and using linear regression analysis. Heat transfer coefficients (convective, evaporative, and radiative) for solar distillation system have been observed to be 2.48–4.09, 13.25–52.38, and 8.75–9.66 W/m²°C, respectively. Overall thermal efficiency and exergy efficiency for the distillation system has been found to be 18.77% and 1.2%, respectively. The convective heat transfer coefficient for potato slices are observed higher for initial hours and decreases as the day progresses. The average convective heat transfer coefficients for bitter gourd and potato slices have been observed as 2.18 and 5.04 W/m²°C, respectively. Experimental error in terms of percent uncertainty for bitter gourd and potato slices are found to be 42.93% and 37.06%, respectively. The present design of solar distillation and drying in a single unit could be beneficial for the development of remote, arid, and rural areas.     

A real-time simulating non-isothermal mathematical model for the passive feed direct methanol fuel cell

In order to understand the complex transport phenomena in a passive direct methanol fuel cell (DMFC), a theoretical model is essential. The analytical model provides a computationally efficient framework with a clear physical meaning. For this, a non-isothermal, analytical model for the passive DMFC has been developed in this study. The model considers the coupled heat and mass transport along with electrochemical reactions. The model is successfully validated with the experimental data. The model accurately describes the various species transport phenomena including methanol crossover and water crossover, heat transport phenomena, and efficiencies related to the passive DMFC. It suggests that the maximum real efficiency can be achieved by running the cell at low methanol feed concentration and moderate current density. The model also accurately predicts the effect of various operating and geometrical parameters on the cell performance such as methanol feed concentration, surrounding temperature, and polymer electrolyte membrane thickness. The model predictions are in accordance with the findings of the other researchers. The model is rapidly implementable and can be used in real-time simulation and control of the passive DMFC. This comprehensive model can be used for diagnostic purpose as well.     

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.     

城市热力景观格局季节变化特征分析及其应用

热岛效应是城市发展过程中所产生的特有的环境问题,已经成为一种城市环境公害,对其形成和演变规律的研究有助于人们提出有效的应对措施。热力景观是分析城市热岛空间格局的一种新方法。以厦门为研究对象,利用2002年1、2、3、8、12月的Landsat ETM＋影像数据进行地表温度反演,在此基础上使用景观格局指数分析厦门城市热力景观格局的季节变化特征。结果表明：厦门城市热岛在夏季（8月）最强,春秋次之,冬季（1月）最弱。该变化特征是城市地表吸收太阳辐射和人为废热排放随季节变化的共同结果。应用该方法对2002年厦门热污染源进行调查,发现当年共有热污染源26个,其中工业热污染源18个。该研究可为环保、能源等部门乃至于整个城市的规划管理提供有力的决策依据。     

Bradford法测定土壤球囊霉素相关蛋白的影响因子

土壤球囊霉素相关蛋白(glomalin-related soil protein,GRSP)是评价土壤健康的重要指标。研究了土样粒径、贮存条件和高温提取后离心延误时间3个影响因子对采用Bradford法测定GRSP含量的作用效果。结果表明,土样粒径对易提取GRSP(EEG)的提取测定影响显著,过0.074 mm孔径筛土样中提取出的EEG含量高于过0.149、0.25、1 mm孔径筛的土样;总GRSP(TG)含量的测定结果对土样粒径的变化没有明显响应,测定TG含量可采用过1 mm孔径筛的土样。贮存条件影响EEG和TG含量的测定,有机质含量低的土样室温保存18个月条件下测得的EEG含量低于-20℃保存条件下;有机质含量高的土样室温保存条件下测得的EEG含量高于-20℃保存条件下;室温保存条件下3个有机质含量水平的土样TG含量均高于-20℃保存条件下。不同样品保存方式间3个有机质含量水平的土样EEG或TG含量差异均显著。为减小有机质降解等的影响,宜低温保存土样。提取后延误离心将导致EEG含量测定值降低,因此延误时间以控制在1 h之内为宜;离心延误2 h内不同延误时间之间测得的TG含量无显著差异。     

城市热岛效应下浅层土中混凝土的酸腐蚀试验研究

针对城市热岛效应引起城区浅层土地温场升高这一观测结果,采用室内快速模拟试验方法,对城区酸性土壤腐蚀混凝土材料的温度效应开展了试验研究.试验研究了在温度为5℃、20℃和40℃条件下,混凝土试样在酸浓度分别为0%、5%和10%的沙土介质中放置30 d、90 d后的抗压强度变化规律,并对混凝土试样在腐蚀过程中的腐蚀系数变化规...     

生物吸附/MBR/硫铁自养反硝化组合工艺运行特性及蛋白质源污泥增量研究

为实现污水处理的深度脱氮除磷及蛋白质源污泥增量,进行了生物吸附/MBR/硫铁自养反硝化组合工艺处理城镇污水的试验研究.结果表明,生物吸附池可以快速富集进水中的大部分有机物,COD平均去除率为55.1%,剩余污泥采用厌氧发酵方式处理,用于生产优质碳源.通过组合工艺系统中的硝化、硫自养反硝化及铁屑除磷作用,出水氨氮、总氮和总磷分别达到1、5和0.4 mg·L~(-1)以下.优质碳源投加到MBR工艺段,碳源环境的改善使得污泥增长率从0.17 g VSS/g COD提高至0.49 g VSS/g COD,进水中总氮的同化比例从40%提高至59%.此外,污泥中蛋白质及氨基酸含量也显著增长,增长率分别为18.3%和19.7%.组合工艺在获得高排放标准水质的同时,实现了高蛋白质源污泥的增量,可为污泥资源化利用提供优质原料.