SBR法处理麻生物脱胶废水的T艺实验研究St

采用SBR法处理麻生物脱胶废水，实验考察了溶解氧、曝气时间、污泥负荷与处理效果的关系。结果表明，在限制性曝气及COD     

腈纶污水的分质处理

介绍某公司腈纶污水的水质特点，处理工艺、主要设备及构筑物设计参数。该污水预处理装置运行以来，处理效果良好，符合后续生化处理的进水要求。     

Enzyme-Retted Flax Fiber and Recycled Polyethylene Composites

Municipal solid wastes generated each year contain potentially useful and recyclable materials for composites. Simultaneously, interest is high for the use of natural fibers, such as flax (Linum usitatissimum L.), in composites thus providing cost and environmental benefits. To investigate the utility of these materials, composites containing flax fibers with recycled high density polyethylene (HDPE) were created and compared with similar products made with wood pulp, glass, and carbon fibers. Flax was either enzyme- or dew-retted to observe composite property differences between diverse levels of enzyme formulations and retting techniques. Coupling agents would strengthen binding between fibers and HDPE but in this study fibers were not modified in anyway to observe mechanical property differences between natural fiber composites. Composites with flax fibers from various retting methods, i.e., dew- vs. enzyme-retting, behaved differently; dew-retted fiber composites resulted in both lower strength and percent elongation. The lowest level of enzyme-retting and the most economical process produces composites that do not appear to differ from the highest level of enzyme-retting. Flax fibers improved the modulus of elasticity over wood pulp and HDPE alone and were less dense than glass or carbon fiber composites. Likely, differences in surface properties of the various flax fibers, while poorly defined and requiring further research, caused various interactions with the resin that influenced composite properties.     

HFBM工艺处理三羟甲基丙烷废水的中试研究

采用厌氧滤池+HFBM工艺处理三羟甲基丙烷废水,在进水CODCr浓度小于10 000 mg.L-1、水力停留时间为96 h条件下,出水CODCr浓度稳定在500 mg.L-1以下,在进水中含0.5%甲醛条件下,经过7 d的冲击试验,出水CODCr浓度仍能保证在500 mg.L-1以下,中试试验直接运行费用为6.96元/t废水。     

活性炭纤维对水中微囊藻毒素的吸附性能

利用活性炭纤维对水中微囊藻毒素MC—LR的吸附，研究了吸附过程的热力学与动力学特性。结果表明，活性炭纤维对MC—LR的平衡吸附量在相同温度下随MC-LR初始浓度的增加而显著增大，并随着温度升高而增加，最大吸附量达246μg／g。不同温度条件下，活性炭纤维对MC-LR的吸附均较好地符合Langmuir等温吸附模型。通过热力学分析发现，△H=15．7kJ／mol、△G〈0、△S〉0，表明该吸附是自发的、吸热的过程，温度升高有利于吸附反应。动力学研究表明，该过程符合一级动力学方程。吸附反应速率受颗粒内扩散和液膜扩散共同影响。活性炭纤维经再生后，平衡吸附量变化较小，具有良好的重复使用性能。     

高性能纤维在个体防护装备上的应用现状及前景分析

高性能纤维是从化学纤维演化而来，是指耐高温、耐气候、耐化学腐蚀、质量轻、强度高、模量高的特种纤维材料。本文结合几种典型的高性能纤维的具体性能，对高性能纤维在个体防护装备上的应用现状及前景作了分析，旨在进一步推动高性能纤维在个体防护装备上的应用，从而在不同的使用情况下增强个体防护装备对人体的保护功能。     

阴极氧还原产电生物可渗透反应栅的研究Ⅰ. 不锈钢毛电极模拟反应器

提出利用阴极氧还原和阳极微生物产电作用的产电生物可渗透反应栅（CORE-PRB）方法用于被有机物污染的地下水的修复,并以不锈钢毛为电极建立模拟反应装置验证了CORE-PRB的技术概念。实验中考察了分别以蔗糖＋醋酸盐和不同浓度的污泥消化液为进水时的反应电流,并研究电极距离对反应电流的影响。由于氧还原阴极阳极反应能力的限制,随着与阴极室距离加大,模拟反应装置各阳极室的电流迅速减小。有机基质的可生化性对模拟反应器的总电流也有显著影响。     

一步法制备乙酸酐新工艺

本文提供了一步法制备乙酸酐的新工艺。它具有工艺简单、反应快、转化率高等优点,是小批量生产乙酸酐的最佳方法。     

The Effect of Hydroxyl Radical Generation on Free-Radical Activation of TMP Fibers

The purpose of this work was to study the mechanisms involved in free radical activation of thermal mechanical pulp (TMP) fibers with the ultimate goal of developing methods for bonding wood fiber without the use of traditional adhesives. The generation of hydroxyl radicals in a mediated Fenton system was studied using electron spin resonance (ESR) spin-trapping techniques and indirectly through chemiluminescence measurement. The activation of TMP fibers was also evaluated by ESR measurement of free phenoxy radical generation on solid fibers. The results indicate that low molecular weight chelators can improve Fenton reactions, thus in turn stimulating the free radical activation of TMP fibers. However, it was also shown that excessive and prolonged free radical treatment may cause the destruction of fiber phenoxy radicals. In conclusion, this study demonstrates the potential for application, but also the complexity of free radical chemistry in biological materials, especially with regard to the chelation of transition metals and the interaction between free radicals.     

Sustainable Cellular Biocomposites from Natural Fibers and Unsaturated Polyester Resin for Housing Panel Applications

Increased environmental awareness and interest in long-term sustainability of material resources has motivated considerable advancements in composite materials made from natural fibers and resins, or biocomposites. In spite of these developments the lower stiffness and strength of biocomposites has limited their applications to non-load-bearing components. This paper presents an overview of a study aimed at showing that the shortcomings of biocomposites can be overcome through hybrid material designs and efficient structural configurations to make them suitable for load bearing structural components. Hybrid blends of natural and synthetic fibers can significantly improve the characteristics of biocomposites with minimal cost and environmental impact, and hierarchical cellular designs can maximize material efficiency in structural components. Periodic and hierarchical cellular plate designs made from natural fibers and unsaturated polyester resin were evaluated experimentally and analytically. Stiffness, strength, and dimensional stability of all-biocomposite and hybrid natural–synthetic material systems were evaluated through material tests while structural performance of cellular plate designs was assessed through flexural tests on laboratory-scale samples. The experimental results were correlated with analytical models for short-fiber composites and cellular structures. The results showed that biocomposites have adequate short-term performance and that they can efficiently compete with housing panels made from conventional structural materials.