有限元仿真技术在板材成形中的应用

有限元仿真技术具有很强的经济性和柔性，已广泛应用于汽车钢铁工业领域。文中论述了板材成形有限元仿真分析的关键技术及其研究进展，并采用动力显式有限元软件LS-DYNA对轻型车侧围后外板零件冲压成形过程进行了仿真计算，分析了变形过程的金属流动规律。     

润滑油高效降解菌的筛选及降解性能

实验以被石油污染的土壤为出发菌源,以润滑油为唯一碳源,经过筛选分离得到4株对润滑油具有降解能力的菌株。经过形态观察、生理生化实验初步鉴定发现,4株菌株分别为黄单胞菌属(Xanthomonas)、动胶菌属(Azotobac-ter)、假单胞菌属(Pseudomonas)和黄杆菌属(Flavobacterium),其中菌株G4为黄杆菌属,其润滑油降解效率最高。研究菌株G4降解性能的影响因素发现,实验中的各因素对润滑油降解率的影响大小依次为:温度>葡萄糖浓度>硫酸铵浓度>pH值。在温度20～40℃下,菌株G4对润滑油均具有一定的降解能力。在适宜的温度范围中,pH值5.0～9.0范围内,菌株G4的润滑油降解率随pH值的变化很小,且均在80%以上。菌株G4在以润滑油为唯一碳源时的最佳培养条件为:温度30℃,pH值为9.0,硫酸铵浓度为1.0 g/L。在此条件下培养36 h,100 mL的G4培养液对200μL润滑油的降解率可达84.6%。     

基因工程菌E.coli BL21-NiCoT吸附镍的性能研究

以表达Staphylococcus aureus ATCC6538镍钴转运酶NiCoT基因的基因工程菌E.coli BL21-NiCoT作为生物吸附剂处理含镍废水.结果表明:基因工程菌在pH为4～9时有比较好的吸附效果,30 min就达到了吸附平衡;基因工程菌对Ni2 的富集容量比原始宿主菌有很大的提高,最大平衡富集量从3.76 mg/g增加到11.33 mg/g,增幅达3倍多,溶液中Ni2 的最大去除率也从原来的35.62%增加到91.23%;Cu2 、Cr6 、Zn2 等的存在对吸附没有很大的影响.镍进入细胞内后与羟基和酰胺基团发生结合,蛋白类物质和含羟基类物质在细胞内富集镍的过程中起到重要作用;基因工程菌转接10、20、30、40、50次,重组质粒保持良好的结构稳定性,基因工程菌对镍的富集能力也具有较好的稳定性.     

油烟污染物降解优势菌株的筛选及性能研究

在完成对活性污泥驯化的基础上,分离、纯化出XJ9,XJ30,XJ2,XJ21,XJ28,XJ25等6株油烟污染物降解细菌,研究其生长条件及降解性能,筛选出一株优势菌株并进行菌落形态学及分子生物学鉴定。实验结果表明:6株细菌最适生长温度在35℃左右、最适pH在6⁸之间、最佳摇床转速介于808之间、最佳摇床转速介于80¹60 r/min之间,各菌株最佳降解时间均为36 h,对油烟污染物的降解率介于12%160 r/min之间,各菌株最佳降解时间均为36 h,对油烟污染物的降解率介于12%⁶0%之间,其中XJ25最高可达到60%左右,可确定XJ25为油烟污染物降解优势菌株。经分子生物学鉴定,确定XJ25为干燥棒状杆菌(Corynebacterium xerosis)。所获得的油烟污染物降解菌对于应用生物法降解餐饮油烟污染物具有一定的价值。     

石油烃类降解菌分离筛选及其特性的实验

通过选择性培养从被石油污染土壤中分离出2株能够以机油为碳源和能源的菌株LL1和LL2,测定了温度、底物浓度和pH值对其降解能力的影响,确定了最佳生长条件,并试验了菌株对正己烷、苯和甲苯的降解能力。实验表明,2种菌株都对机油有较强的降解能力,在实验最适条件下分别达到53%和77%,其中LL2菌株还对苯和甲苯有一定的降解能力,具有较好的应用前景。     

Degradation and mineralization of 2-chioro-, 3-chloro- and 4-chlorobiphenyl by a newly characterized natural bacterial strain isolated from an electrical transformer fluid-contaminated soil

A bacterium classified as Achromobacter xylosoxidans strain IR08 by phenotypic typing coupled with 16S rRNA gene analysis wasisolated from a soil contaminated with electrical transformer fluid for over sixty years using Aroclor 1221 as an enrichment substrate.The substrate utilization profiles revealed that IR08 could grow on all three monochlorobiphenyls (CBs), 2,4'- and 4,4'-dichlorobiphenylas well as 2-chlorobenzoate (2-CBA), 3-CBA, 4-CBA, and 2,3-dichlorobenzoate. Unusually, growth was poorly sustained on biphenyland benzoate. In growth experiments, IR08 degraded all CBs (0.27 mmol/L) in less than 96 h with concomitant stoichiometric release ofinorganic chloride and growth yields were 2-3 times higher than those observed on biphenyl. In contrast to most of the chlorobiphenyl-degrading strains described in the literature, which are reported to form CBA, no metabolite was identified in the culture broth byHPLC analysis. When co-incubated with respective CBs and biphenyl, strain IR08 preferentially utilized the chlorinated analoguesin less than 96 h while it took another 264 h before 90% of the initially supplied biphenyl could be degraded. The promotion of co-metabolic transformation of halogenated substrates by the inclusion of their non-halogenated derivatives may not therefore, result inuniversal benefits.     

The shaped blasting experimental study on damage and crack evolution of high stress coal seam

In the deep high stress coal and rock mass, the efficiency of the ordinary blasting method is constantly affected by the high pressure. This study investigates the shaped blasting technology with increased blasting efficiency, develops a mechanical model for coal crack expansion during shaped blasting, and examines the force-energy action of energy-gathering jets during coal splitting. The established model was combined with experiments and simulations to reveal the damage and evolution of cracks in coal and rock masses. Experiments demonstrate that shaped blasting can create an energy-gathering jet that causes a directional fracture in the test block. The peak of compressive strain in the energy-gathering direction is 1.12 times greater than that of ordinary blasting, and the static action period of the explosive gas is prolonged by 1.3 μs according to the stress curve. Moreover, the peak pressure strain increased 3.2 times, and the pull strain peak increased 3.92 times. The damage amount was represented by the resistivity and ultrasonic wave speed, and shaped blasting causes 1.2 and 1.5 times greater damage than ordinary blasting. The research results provide technical methods for safe and rapid penetration blasting in deep high-ground stressed coal mines.