甲醇燃料发动机排气中的亚硝酸甲酯和硝酸甲酯的分析

为了测定使用甲醇燃料的发动机排气里的亚硝酸甲酯(MeONO)和硝酸甲酯(MeONO_2)含量,建立了色谱分析方法。本方法的最小检测限MeONO为20ppb,MeONO_2为50ppb。对自制的MeONO和MeONO_2进行了质谱鉴定,并对所制备的一定浓度的样品进行了稳定性考察。应用本方法测定了甲醇机排气中的MeONO含量为5ppm—250ppm,MeONO_2含量为<50ppb。     

中型上流式厌氧污泥床处理甲醇废水启动初期工艺参数控制

介绍了上流式厌氧污泥床处理甲醇废水工业装置启动初期应注意的几个问题,包括温度控制,污泥搅拌,进水方式,进水浓度及异常情况处理等,给出了具全的工艺参数。     

Biodegradation of mixture of VOC''''s in a biofilter

IntroductionDeterioratingatmosphericairqualityhasresultinginmorestringentregulationsarebeingenforcedtocontrolairpollutants .Volatileorganiccompounds(VOCs)areamongthenewclassofaircontaminantsgeneratedfromavarietyofindustrialsources .Effortstocontroltheemis…     

甲醇燃料汽车排气净化

在燃用纯甲醇(M100)的BJ492Q型四冲程发动机的台架试验中,用堇青石蜂窝金属钯催化剂进行了排气净化试验。在发动机的混合比调整和负荷特性试验条件下观察了排气中甲醇、甲醛和一氧化碳的净化效果,观察了发动机的怠速起动和暖机过程中催化剂的净化性能。结果表明,发动机排气经催化净化后,排气中甲醇、甲醛和一氧化碳的浓度分别降低到3—17ppm,1—13ppm和0.01—0.30%;净化率分别达到93—99%,92—98%和80—99%。在发动机怠速起动和暖机过程中催化剂可点燃发挥净化作用。制作了催化箱,在武汉213型越野客货车上初步考察了其实用性能。     

高等植物对甲醇的释放和利用

植物可向大气中释放一种挥发性的有机气体——甲醇,同时对这种气体可加以利用。在详细阐述甲醇的产生、释放和可能的代谢机制的基础上,通过不同浓度的甲醇溶液喷施牡丹叶片,测定其对光合作用过程及叶绿素荧光参数变化的影响。结果表明,光合作用有较大改善:光合速率明显提高,气孔导度增加,叶内CO2浓度也有一定幅度改善。叶绿素荧光参数(qN和NPQ)以及电子传递速率(ETR)发生较大改变;Fm/Fo,Fv/Fo和ΦPSII的下降可能与甲醇对牡丹叶片的双向效应(促进性和毒性)有关,这取决于喷施的浓度、次数和时间。初步的结果显示:甲醇提高光合作用速率的同时,并没有伴随光合效率和机能的改善和提高。期间的气孔导度和胞内CO2浓度的提高以及非辐射能耗散(qN和NPQ)和光呼吸的降低可能是牡丹叶片光合作用速率提高的主要原因。     

废水中甲醇分析方法的研究

建立了废水中甲醇的3种分析方法，毛细管柱气相色谱法、填充柱气相色谱法和变色酸分光光度法。测定废水中甲醇浓度相对标准偏差分别为1．45％，2．93％，3．61％，平均回收率分别为100．88％，98．19％，97．62％。实验结果表明：3种方法能较好对应，其中毛细管柱气相色谱法灵敏度最高，方法检出限为0．05mg／L。     

Aqueous and organic extracts of Trigonellafoenum-graecum L. Inhibit the mycelia growth of fungi

Aqueous extracts from various plant parts of fenugreek(3%)(aerial parts:leaves and stems(LS),roots(R),ground seeds(GS)and not ground seeds(NGS))and petroleum ether,ethyl acetate and methanolic fractions of the aerial parts were assayed to determine their antifungal potential against Botrytis cinerea,Fusarium graminearum,Alternaria sp.,Pythium aphanidermatum,and Rhizoctinia solani.All fenugreek plant parts showed antifungal potential and the magnitude of their inhibitory effects was species and plant parts d...     

百喜草茎叶发酵前后甲醇溶提物对离体条件下AM真菌的生长效应

发酵前后百喜草（Paspalum notatum Fl     

Optimization and evaluation of a bottom substrate denitrification tank for nitrate removal from a recirculating aquaculture system

A bottom substrate denitrification tank for a recirculating aquaculture system was developed. The laboratory scale denitrification tank was an 8 L tank (0.04 m2 tank surface area), packed to a depth of 5 cm with a bottom substrate for natural denitrifying bacteria. An aquarium pump was used for gentle water mixing in the tank; the dissolved oxygen in the water was maintained in aerobic conditions (e.g. > 2 mg/L) while anoxic conditions predominated only at the bottom substrate layer. The results showed that, among the four substrates tested (soil, sand, pumice stone and vermiculite), pumice was the most preferable material. Comparing carbon supplementation using methanol and molasses, methanol was chosen as the carbon source because it provided a higher denitrification rate than molasses. When methanol was applied at the optimal COD:N ratio of 5:1, a nitrate removal rate of 4591 ± 133 mg-N/m2 tank bottom area/day was achieved. Finally, nitrate removal using an 80 L denitrification tank was evaluated with a 610 L recirculating tilapia culture system. Nitrate treatment was performed by batch transferring high nitrate water from the nitrification tank into the denitrification tank and mixing with methanol at a COD:N ratio of 5:1. The results from five batches of nitrate treatment revealed that nitrate was successfully removed from water without the accumulation of nitrite and ammonia. The average nitrate removal efficiency was 85.17% and the average denitrification rate of the denitrification tank was 6311 ± 945 mg-N/m2 tank bottom area/day or 126 ± 18 mg-N/L of pumice packing volume/day.