气浮+生物接触氧化工艺处理食品加工废水

通过气浮 生物接触氧化工艺处理速冻食品加工废水的实验、设计和工程运行,结果表明:废水COD去除率能达到97%以上,使得最终出水的COD＜100mg/l.该工艺对冲击负荷有较强的适应性.     

2008年湖南低温雨雪冰冻天气分析与数值模拟

利用湖南省地面观测站点资料、探空资料、NCEP再分析资料及海温资料对该省2008年1月中旬至2月上旬异常低温雨雪冰冻天气形成原因进行了分析,结果表明:长时间的大气环流异常是造成此次低温雨雪冰冻天气的主要大气环流背景;温度的垂直结构分析表明,925~700hPa长时间存在强的逆温层,为冰冻提供了有利的形成环境;海温异常对气温有一定的影响作用,在拉尼娜起始年,湖南冬季平均气温偏低,出现冷冬的概率较大。通过中尺度数值天气预报模式MM5的模拟,也间接印证了冰冻的形成过程。最后,针对此异常低温雨雪冰冻天气发生特点,提出在气候变暖的大背景下仍要加强冬季极端气象灾害的研究和防范,同时加强和完善灾情上报制度。     

FROZEN SOIL IMPACT ON GROUND WATER‐SURFACE WATER INTERACTION1

ABSTRACT: Ground water and surface water interaction in the prairie pothole region of the United States and Canada is seasonally dominated by the presence of thick, frozen soil layers that affect infiltration. During a spring thaw, the subsoil may remain frozen, preventing infiltration. The impact of the frozen soil layer on the timing of infiltration of depressional‐focused recharge to the ground water is not clearly understood. The objective of this paper is to relate changes in the water table during spring to changes in frost depth and soil water content. A depression and adjacent upland study site were instrumented with CRREL‐type frost tubes, neutron probe access tubes, and ground water monitoring wells. Increases in water table levels in a depression occurred before the frost layer decomposed and infiltrating water quickly formed a recharge mound. Water table responses at the upland site took place as two events. The first event was a gradual rise, probably caused by the lateral dissemination of the recharge mound. The second rise was a rapid rise coinciding with the decomposition of the soil frost layer. Because of the accumulation of surface water in depressions, agricultural practices that remove water from a field can affect water resources management by limiting the addition of water recharge to unconfmed ground water.     

乌梁素海冰盖中微塑料的分布特征及其与盐度、叶绿素a的响应关系

目前关于淡水湖泊冰盖中微塑料的分布特征研究还鲜见报道.为阐明乌梁素海冰盖中微塑料的赋存特征以及其与冰盖盐度、叶绿素a浓度之间的响应关系,通过野外采样、显微镜观察、傅里叶红外光谱测定和相关性分析等方法,对冰封期乌梁素海冰盖中微塑料的丰度、颜色、形状和种类进行鉴定,通过相关性分析探求微塑料在冰盖中的分布特征及其与盐度、叶绿...     

黏土地层联络通道冻结壁厚度优化设计及应用研究*

为解决传统冻结壁设计方法不能真实、合理地反映黏土地层中联络通道冻结壁实际受力情况,进而导致冻结壁厚度设计过于保守的问题,结合黏土地层直墙拱形冻结壁实际受力特点,基于对冻结壁支护压力的合理计算,提出1种适用于黏土地层冻结壁厚度设计的优化方法。结果表明:与传统设计方法相比,该方法所确定冻结壁支护压力与实际施工环境中冻结壁受力状态吻合效果更好,并且能够提供合理的安全储备;经数值计算和现场应用验证,计算所得冻结壁设计方案可以满足施工环境中的承载力及变形稳定性要求;且相较传统设计方案,所得方案兼具安全性与经济性,可有效规避因设计过于保守和冻结周期过长引起的冻胀、融沉变形过大等工程灾害的风险;该方法高效、易行,可为传统冻结壁设计方法提供必要补充,亦可为类似工程的施工设计提供有益参考。     

重金属元素在冻土与融土中迁移的对比试验

随着寒区经济的发展,冻土地区的矿山开采活动不断加剧,随之产生的重金属污染问题也越来越严重.冻土地区生态环境脆弱,一旦受到破坏就很难恢复.针对此问题,室内模拟了尾矿矿渣在冻土与融土中的填埋及其对填埋场周边土体的影响,通过检测填埋场各处土壤的温度、含水量以及重金属元素的含量,发现温度和水分对重金属元素的迁移影响很大.土壤温度越低,重金属元素的迁移越慢;在温度梯度的作用下,重金属元素均随着水分从土体的暖端向冷端迁徙并聚集于冻结锋面.重金属元素在冻土中的迁移比融土中慢,表明冻土环境不利于重金属元素的迁移.在土壤质地、温度和含水量等相同的情况下,Zn的迁移性较强,Pb和Cu的迁移性相对较弱.     

菠萝蜜的保鲜及其市场开发前景

介绍了菠萝蜜的基本生物特性,综合分析了食用价值,提出了对其进行速冻或凝胶保鲜的加工方法,这为消费者常年提供营养、美味的热带水果－菠萝蜜成为可能,同时也为加工企业提供了一条合理、有价值的开发途径。     

1982～2008年东北冻土区植被生长季NDVI对气候变化和CO_2体积分数增加的响应

利用GIMMS和MODIS两种遥感数据,分析了1982～2008年东北冻土区植被生长季平均NDVI的时空特征,并探讨不同类型冻土区和不同植被类型归一化差值植被指数(NDVI)对气候变化和CO2体积分数增加的响应.研究表明,不同冻土类型区植被生长季NDVI均值从大到小依次为:连续多年冻土区大片多年冻土区季节性冻土区岛状多年冻土区.东北冻土区不同植被类型生长季平均NDVI值由大到小依次为:森林灌丛沼泽农田草地,其中森林植被生长季平均NDVI值为0.61,草地为0.46.过去27年间,东北冻土区植被生长季平均NDVI年际变化曲线可分为3个变化阶段:①1982～1990年,小幅上升阶段;②1990～2000年,缓慢下降阶段;③2000～2008年,明显上升阶段.1982～2008年期间,连续多年冻土区及大片多年冻土区植被生长季平均NDVI值呈显著上升趋势(p0.05).对于不同植被类型而言,除森林植被NDVI呈显著上升趋势外(p0.05),其它植被类型NDVI值无显著变化趋势.过去27年间,东北冻土区年均气温显著升高,年降水量显著下降,CO2浓度显著升高.研究区全区平均NDVI与年平均气温呈显著正相关(p0.05),气温是影响东北冻土区生长季植被NDVI的主要气候因子.森林和沼泽湿地植被生长季平均NDVI与年平均气温呈显著正相关,与降水量呈显著负相关(p0.05);5种植被类型中仅森林植被受CO2浓度影响显著.年平均气温对不同植被类型的影响由高到低的顺序为:森林沼泽湿地灌丛农田草地;降水的影响为:森林沼泽湿地草地灌丛农田;CO2浓度的影响为:森林沼泽湿地草地农田灌丛.     

冷冻取芯过程煤芯瓦斯解吸特性试验研究*

为探究冷冻取芯过程煤芯瓦斯解吸特性,基于模拟试验的相似性,依托自主研发的含瓦斯煤冷冻取芯响应特性测试平台,开展不同变质程度煤样（长焰煤、贫瘦煤、无烟煤）及不同吸附平衡压力（1.0,2.0,3.0,4.0 MPa）下冷冻取芯过程煤芯瓦斯解吸特性试验研究。研究结果表明:冷冻取芯过程中,煤芯瓦斯解吸量与吸附平衡压力及煤变质程度呈正相关关系;在煤芯瓦斯解吸过程中存在倒吸现象,煤与瓦斯初始吸附平衡压力越大,煤的变质程度越高,倒吸开始时间越迟;冷冻取芯过程中,瓦斯解吸速度与吸附平衡压力及煤变质程度呈正相关关系,且瓦斯解吸速度随吸附平衡压力及煤变质程度变化曲线符合幂函数关系。     

Assessment of future climate change impacts on water-heat-salt migration in unsaturated frozen soil using CoupModel

• A model coupling water-heat-salt of unsaturated frozen soil was established. • Future temperature, precipitation, and evaporation increase in freeze–thaw period. • Soil water, heat, and salt transport are closely coupled during freeze–thaw period. • Freeze–thaw cycles and future climate change can exacerbate salinization. The transport mechanisms of water, heat, and salt in unsaturated frozen soil, as well as its response to future climate change are in urgent need of study. In this study, western Jilin Province in north-eastern China was studied to produce a model of coupled water-heat-salt in unsaturated frozen soil using CoupModel. The water, heat, and salt dynamics of unsaturated frozen soil under three representative concentration pathway (RCP) scenarios were simulated to analyze the effects of future climate change on unsaturated frozen soil. The results show that water, heat, and salt migration are tightly coupled, and the soil salt concentration in the surface layer (10 cm) exhibits explosive growth after freezing and thawing. The future (2020–2099) meteorological factors in the study area were predicted using the Statistical Downscaling Model (SDSM). For RCP2.6, RCP4.5, and RCP8.5 scenarios, future temperatures during the freeze–thaw period increased by 2.68°C, 3.18°C, and 4.28°C, respectively; precipitation increased by 30.28 mm, 28.41 mm, and 32.17 mm, respectively; and evaporation increased by 93.57 mm, 106.95 mm, and 130.57 mm, respectively. Climate change will shorten the freeze–thaw period, advance the soil melting time from April to March, and enhance water and salt transport. Compared to the baseline period (1961–2005), future soil salt concentrations at 10 cm increased by 1547.54 mg/L, 1762.86 mg/L, and 1713.66 mg/L under RCP2.6, RCP4.5, and RCP8.5, respectively. The explosive salt accumulation is more obvious. Effective measures should be taken to prevent the salinization of unsaturated frozen soils and address climate change.