牛粪堆肥升温菌剂的筛选及其作用机制

以糖、淀粉、蛋白质、纤维素培养基及菌株增殖倍数、菌株性能等为筛选方法,从牛粪低温堆肥中筛选不同原料重要功能菌并组成功能菌剂;以不同类别原料菌及单菌株发酵实验对升温机制进行研究。结果表明,芽孢杆菌、假单胞菌、纤维单胞菌及小孢霉菌等为重要功能菌;菌剂起温快,升温效果好,48 h堆体即由低温进入中温,5 d达到高温,腐熟时间可缩短至约17~18 d;糖功能菌升温效果最为显著,淀粉及蛋白质功能菌次之,纤维素功能菌升温能力较弱;菌株利用各种原料能力越强,增殖速度越快,对升温作用越大。各菌株充分利用基质各成分,紧密协同和促进,是低温堆体发酵升温的主要作用机制。     

呼和浩特市奶牛养殖业污染现状及防治对策

通过对呼和浩特市奶牛养殖污染状况调查,提出相应防治对策。     

牛粪堆肥系统环境因子对抗性基因的影响

本研究利用实时定量PCR技术检测牛粪60 d好氧堆肥过程中典型四环素类抗性基因(tet Q、tet W、tet M、tet G、tet A和tet X)和大环内酯类抗性基因(erm35、erm36、erm B、erm F、erm T和erm X)的数量变化规律,系统研究了温度、含水率、挥发性有机质(VS)含量、碳氮比(C/N)、pH值、氧化还原电位(ORP)等堆肥系统环境因子和细菌数量(TCB)对这两类典型抗生素抗性基因的影响.结果表明,堆肥升温阶段牛粪中tet Q、tet W、tet G和tet X数量分别增加1. 7、0. 3、84. 8和4. 5倍,而tet M丰度降低了83. 1%;堆肥腐熟阶段牛粪中tet G和tet X数量分别增加23. 8和11. 5倍,而tet W、tet Q和tet M数量均降低90%.整个牛粪堆肥过程中erm35、erm36、erm B、erm F、erm T和erm X丰度分别增加2. 1、430. 4、0. 6、11. 5、2. 1和49. 1倍. RDA分析表明,牛粪堆肥过程中对四环素与大环内酯类抗性基因数量影响较大的3个环境因子分别为:ORP(54. 8%)、温度(34%)和VS(11. 3%),其中ORP与erm X和erm B、温度与tet Q和erm F以及VS与tet W数量均呈明显地正相关.     

奶牛场废水处理技术研究

本文对奶牛场废水处理工艺进行了研究。结果表明,奶牛场废水经混凝处理后,ＣＯＤｃｒ 从２０１０ ｍｇ／Ｌ 下降到５６３ｍｇ／Ｌ～６９１ ｍｇ／Ｌ,ＮＨ３ － Ｎ 可从７１ ｍｇ／Ｌ 下降到２５ ｍｇ／Ｌ～３３ ｍｇ／Ｌ,ＣＭ 从１８０ 度下降到４０ 度～７０ 度。如采用混凝表面曝气处理工艺,可使奶牛场废水达到国家排放标准,且处理工艺简单、投资少、运行费低、易操作管理     

温度与秸秆比例对牛粪好氧堆肥的影响

为了研究不同C／N比值在不同温度条件下牛粪堆肥30d时的全量养分和有机质的含量情况，提出了以新鲜牛粪和苜蓿秸秆混合物为堆料，在添加1％的生物腐熟剂的基础上，对堆肥温度及C／N比进行调控，并进行交叉实验。结果表明，（1）采用培养箱进行好氧发酵时，在温度为30℃和45℃的环境下堆肥最佳，温度过低或过高都会影响堆肥。（2）牛粪高温好氧堆肥时，添加一定比例的苜蓿秸秆可以调节堆料的C／N比值、含水量，缩短堆肥时间，其中牛粪与秸秆比例为1：l混合堆肥效果较好。（3）堆肥30d时，堆料的TN、TP和TK含量较堆肥初期都有所增加，有机质含量有所降低是因为矿化和释放养分造成的，且各含量均符合国家有机肥标准。     

牛粪自然好氧发酵微生物变化规律

以新鲜牛粪进行好氧堆肥,每间隔3d取样,以牛肉蛋白胨、高氏一号、PDA、豆芽汁为培养基,以稀释法,进行发酵微生物分离、培养、计数和鉴定.结果表明,新鲜牛粪中微生物主要为细菌；发酵过程中,细菌数量大于放线菌、霉菌约104～ 105倍,细菌是发酵过程中的优势微生物；中温性细菌是升温阶段主要作用菌群；嗜热放线菌及嗜热细菌是高温阶段优势菌群；霉菌是降温阶段优势菌群.进一步鉴定表明,细菌类群中的芽孢杆菌、纤维单胞菌,放线菌类群中的小多孢菌、小单孢菌、高温放线菌,霉菌类群中的木霉、曲霉、青霉等为发酵过程中的优势种类.酵母菌未参与发酵过程.     

温度对奶牛粪便温室气体排放的影响

采用封闭罐-气相色谱法对4种不同温度处理下奶牛粪便温室气体排放速率进行测定.结果表明,温度是影响奶牛粪便温室气体排放的主要因子,温度较低时奶牛粪便温室气体排放速率低,而且随着奶牛粪便处理温度升高而增大.在5、15、25和35℃4个处理中,奶牛粪便CO2排放速率两两之间差异显著;CH4排放速率除了5和15℃处理差异不显著之外,其他两两处理之间差异显著;35℃处理时N2O排放速率与其他温度的排放速率差异均显著,其他两两处理之间差异不显著.     

Effects of a gradually increased load of fish waste silage in co-digestion with cow manure on methane production

This study examined the effects of an increased load of nitrogen-rich organic material on anaerobic digestion and methane production. Co-digestion of fish waste silage (FWS) and cow manure (CM) was studied in two parallel laboratory-scale (8 L effective volume) semi-continuous stirred tank reactors (designated R1 and R2). A reactor fed with CM only (R0) was used as control. The reactors were operated in the mesophilic range (37 °C) with a hydraulic retention time of 30 days, and the entire experiment lasted for 450 days. The rate of organic loading was raised by increasing the content of FWS in the feed stock. During the experiment, the amount (volume%) of FWS was increased stepwise in the following order: 3% – 6% – 13% – 16%, and 19%. Measurements of methane production, and analysis of volatile fatty acids, ammonium and pH in the effluents were carried out. The highest methane production from co-digestion of FWS and CM was 0.400 L CH4 gVS^?1, obtained during the period with loading of 16% FWS in R2. Compared to anaerobic digestion of CM only, the methane production was increased by 100% at most, when FWS was added to the feed stock. The biogas processes failed in R1 and R2 during the periods, with loadings of 16% and 19% FWS, respectively. In both reactors, the biogas processes failed due to overloading and accumulation of ammonia and volatile fatty acids.     

Influence of cow-dung amendment on glyphosate mobility in soil

Abstract

Sorption and desorption characteristics of glyphosate on native soil and soil amended with cow dung were investigated. Sorption was pH dependent and decreased with increasing pH. Glyphosate partition coefficient ranged from 275 to 16,200?L kg^?1 in native soil, but for soil amended with cow dung it was significantly lower, viz 180–1530?L kg^?1. Glyphosate partition coefficient showed strong negative correlation with cation exchange capacity and positive correlation with surface area. Phosphate in cow dung suppressed glyphosate sorption and enhanced desorption. This study revealed that cow-dung addition to soil could raise the mobility of glyphosate towards groundwater contamination due to the presence of phosphate.     

KOH活化法制备牛粪活性炭的研究

以牛粪为原料,采用KOH活化法制备活性炭,并考察了浸渍比、活化剂浓度、活化时间和活化温度等不同制备条件对牛粪活性炭样品性能的影响.实验结果表明,在浸渍比1∶4、KOH质量分数35%、活化时间60min、活化温度700℃条件下制备的活性炭性能最佳,制得的活性炭比表面积为979.8m2·g-1,碘吸附值可达796.37mg·g-1,亚甲基蓝吸附值可达150.30mg·g-1.最后,将制备的牛粪活性炭应用于对Cr(Ⅵ)的吸附,研究了最佳工艺条件下制备的活性炭吸附Cr(Ⅵ)的适宜条件.结果表明,在投加量为8g·L-1时、吸附时间90min、pH值为5和较低温度的适宜条件下,自制牛粪活性炭对Cr(Ⅵ)的吸附量最大.