垃圾渗滤液发酵产氢和产甲烷特性研究

以实际垃圾渗滤液作为厌氧发酵基质,研究了初始pH为7.0、中温(37℃)条件下的发酵产氢、产甲烷特性。结果表明,利用垃圾渗滤液作为基质发酵产氢或甲烷时,氢气的最大累积产量为24.33mL(以每克COD计,下同),甲烷的最大累积产量为91.59mL,产氢发酵在初期存在明显的迟滞期,但是产甲烷发酵不存在明显迟滞期;产氢发酵的液相末端产物中含有大量的挥发性有机酸和乙醇,乙醇、乙酸、丁酸质量浓度分别为487.23、1 175.21、1 225.78mg/L,相比产氢发酵,产甲烷发酵的液相末端产物中乙醇、乙酸、丁酸质量浓度均较低,分别为256.38、106.73、107.42mg/L;产甲烷发酵的最终pH是6.32,接近中性,而产氢发酵的最终pH为4.21,呈明显酸性;产甲烷发酵对COD的去除率(41.78%)高于产氢发酵对COD的去除率(32.14%),可能是产氢发酵液相末端产物中的乙酸能被产甲烷菌利用,而被进一步降解。     

产糖脂类生物表面活性剂菌株鉴定及发酵条件优化

从胜利油田污水中筛选出的产生物表面活性剂菌株Bbai-1,经过生理生化鉴定及16S rDNA系统发育学分析确定其属于类短短芽孢杆菌属(Brevibacillus parabrevis),由建立的该菌株的系统发育树可知菌株Bbai-1与其他类短短芽孢杆菌类同源性较低,是一个新的种.薄层色谱和红外光谱分析结果表明此菌株所产的生物表面活性剂为一种新型的糖脂类生物表面活性剂.通过产量和表面张力双重指标对菌株Bbai-1产生物表面活性剂的条件进行优化,确定了其最佳发酵温度为25℃、盐度为8 g/L、pH为7.5.在最佳发酵条件下,生物表面活性剂的产量可达0.9764 g/L.此糖脂类生物表面活性剂具有较高的降低表面张力能力,在浓度为其临界胶束浓度(120 mg/L)时,可将水溶液的表面张力从66.15 mN/m降低至27.62 mN/m.     

耐热乳杆菌的分离及在食物垃圾乳酸发酵中的应用

食物垃圾在我国城市生活垃圾中占有较大比重.发酵食物垃圾生产乳酸是实现其资源化的有效方法.从厌氧发酵的食物垃圾中分离到一株耐热乳酸菌TY50,根据形态、生理生化特征和16S rDNA序列,确定该菌株属于乳杆菌属的干酪乳杆菌组群(Lactobacillus casei group),其最高生长温度为52℃.TY50发酵食物垃圾生产乳酸的最佳同液比为1:12,最适温度为45 ℃.在pH 5.5～6.0条件下,发酵食物垃圾产生36.29 g/L的乳酸,乳酸体积产牢和转化率(乳峻/垃圾干重)分别达到1.01 g/(L·h)和0.44.     

海带渣废弃物资源化利用以及多功能菌肥固体发酵条件的优化

海带渣是海带加工过程中主要固体废弃物。本实验利用海带渣对生防菌株JGA2(-5)27-2进行固体发酵。实验对不同发酵条件下发酵产物对植物病原真菌寄生曲霉的抑制活性与对发酵产植物激素6-糠氨基嘌呤的能力进行测定。通过单因素实验和响应面实验优化了发酵条件:蔗糖为最优的碳源;硝酸盐为最优的氮源;蔗糖浓度、KNO3浓度、最佳的培养时间、含水量、培养温度、接种量和pH值分别为2.091%、0.507%、8.24 d、60%、35℃、4%和自然pH值。在发酵过程中以添加KNO3的形式向发酵菌肥中加入K+离子。实验证明,利用生防菌株JGA2(-5)27-2进行海带渣的固体发酵生产多功能微生物肥料具有可行性,并为海带渣的资源化在农业领域的利用提供一定参考。     

微生物絮凝剂的发酵培养和诱变研究

对粪产碱杆菌B-20进行发酵培养,观察菌株生长与絮凝剂积累、絮凝性、糖类物质消耗和氧浓度之间的关系,发现菌株的生长与絮凝剂的积累呈正相关,并且发酵培养过程中pH保持在7.2～7.9.通过热诱变获得能够稳定传代的B-2022突变菌株,比较了在不同pH、CaCl2添加量、菌液添加量以及不同温度条件下,其与原菌株B-20的发酵混合液的絮凝率差异,发现热诱变菌株B-2022具有更好的絮凝性能,尤其对pH的适应性较强,最优的絮凝条件为pH=9.0、100 mL高岭土悬浮液中1%(质量分数)CaCl2和发酵混合液添加量都为4 mL.进一步将热诱变菌株B-2022紫外诱变45 s,得到紫外诱变菌株B-2022c,其最佳絮凝率可达94.3%,比原菌株B-20和热诱变菌株B-2022的最佳絮凝率分别提高了2.4%和1.7%.通过化学法、紫外分光光度法和红外分光光度法测得絮凝剂的主要化学成分为糖类物质.     

利用糖蜜废水生产微生物絮凝剂及条件优化和效果实验研究

用糖蜜废水取代葡萄糖作为发酵培养基中的碳源和能源培养微生物絮凝剂产生菌Pseudomonas alcaligenesPS-25。通过单因素试验和正交试验得到该菌株产絮凝剂的最佳培养条件:糖蜜废水COD浓度5 000 mg/L、培养基初始pH值6.5、接种量5%(体积比)、温度30℃、培养时间为72 h、摇床转速160 r/min,在此条件下,PS-25所产絮凝剂对高岭土悬浊液絮凝率达96.75%,并且对多种废水都有较好的净化效果,对废水中浊度和色度的去除率分别在90%和80%以上,COD去除率在73.60%～91.10%。研究表明,用糖蜜废水培养PS-25生产微生物絮凝剂处理废水是完全可行的,从而实现废物的资源化利用。     

微生物絮凝剂产生菌的筛选及其培养条件优化的研究

采用常规的细菌分离纯化方法从土壤中分离出絮凝剂产生菌菌株,经过驯化培养后,以发酵液对高岭土混悬液的絮凝效果为指标,筛选出2株高效絮凝剂产生菌.采用单因素试验方法和正交试验设计方法,分析了影响絮凝效果的主要因素,对2个菌株的最佳培养条件进行了优化研究.结果表明:菌株S3产絮凝剂的最佳培养条件是碳源为葡萄糖(20g/L),氮源为酵母膏(2.5 g/L),培养温度为28℃,初始pH值为8,通气量为50 r/min;菌株S21产絮凝剂的最佳培养条件是乙醇(15 g/L),氮源为复合氮源(酵母膏 脲 硫酸铵)(1.6 g/L),培养温度为28℃,初始pH值为9,通气量为200r/min.     

纳米零价铁和零价铁对餐厨垃圾暗发酵制氢过程铁离子和酶活性的影响

通过投加不同浓度的纳米零价铁(NZVI)和零价铁(ZVI),考察了暗发酵制氢过程中铁离子组成和浓度变化、氢化酶和脱氢酶活性,研究了2种添加剂强化餐厨垃圾高温((55±1)℃)暗发酵制氢的作用机制。结果表明:投加NZVI和ZVI均可提高餐厨垃圾暗发酵制氢性能;当投加100 mg·L~(-1) ZVI时,产氢效果最佳,最大产氢潜力和最大产氢速率分别为425.72 mL和66.32 mL·h~(-1),是投加NZVI实验组的1.64倍和1.34倍,代谢途径是以乙醇型发酵为主的混合型发酵;在投加NZVI和ZVI后,暗发酵制氢末端产物的Fe~(2+)和Fe~(3+)浓度升高,投加300 mg·L~(-1)NZVI和100 mg·L~(-1) ZVI实验组Fe2+浓度最大,是未投加实验组的2倍和1.87倍;与反应前相比,Fe~(2+)显著升高,Fe~(3+)由于微生物利用与转化浓度降低,同时可有效提高氢化酶活性。投加100 mg·L~(-1) ZVI不仅可提高氢化酶活性,还可提高脱氢酶活性。以上结果可为提高餐厨垃圾等复杂有机废物的高效能源化提供参考。     

藻渣添加对玉米秸秆厌氧发酵特征的影响

厌氧发酵是农业废弃物资源化的有效途径之一.将农业废弃物同其他富含氮元素的有机废物混合发酵能够有效地提高产气效率.以玉米秸秆为例,尝试利用藻渣作为添加剂,提高农业废弃物厌氧发酵的性能.实验主要研究了混合发酵比例对沼气产量、甲烷产量、沼渣沼液特征的影响.当玉米秸秆、藻渣和接种污泥的挥发性固体质量分数为10∶ 2∶2时,沼气产率最高可达421.0 mL/g,甲烷产率为218.7 mL/g.沼渣组分分析表明,纤维素和半纤维素降解效率分别为83.7％和68.4％,和对照相比纤维素的降解效率显著提高.结果表明,藻渣的添加能够有效地促进玉米秸秆厌氧发酵产甲烷过程.     

柠檬酸中和废水回用技术研究

本文研究了柠檬酸中和废水回用工艺技术。中和废水经碱（ＮａＯＨ）沉淀和酸（Ｈ２ＳＯ４）中和预处理措施,直接用于发酵配料。实验用菌株Ｃ－９８自黑曲霉ＣＢＸ－１２分离获得。最佳发酵条件：总还原糖１４％～１６％,麦麸２．５％,初始ｐＨ６．５,乙醇１．５％。同传统的柠檬酸废水处理工艺比较,该工艺在投资和运转成本方面具有潜在的优势。     

采用零排放新工艺处理蚀刻废液

广州市某化工厂开发出一套对线路板蚀刻废液进行大规模集中资源化处理的零排放处理新工艺,该工艺通过在固相条件下生成氧化铜并用重力分选的方法将其分离出来,克服了原有工艺的缺陷,使废液中所有的成分能够在较低的处理成本下全部分离回收,无三废排出,达到了清洁生产的要求.对其工艺条件进行深入研究,通过正交试验优化了工艺条件.     

Comparison of arsenic content in pelletized poultry house waste and biosolids fertilizer

Managers of human biosolids have been incorporating the practice of waste pelletization for use as fertilizer since the mid 1920s, and waste pelletization has recently been embraced by some poultry producers as a way to move nutrients away from saturated agricultural land. However, the presence of arsenic in pelletized poultry house waste (PPHW) resulting from the use of organoarsenical antimicrobial drugs in poultry production raises concerns regarding additional incremental population exposures. Arsenic concentrations were determined in PPHW and pelletized biosolids fertilizer (PBF) samples. Pellets were processed using strong acid microwave digestion and analyzed by graphite furnace atomic absorption spectroscopy. The mean arsenic concentration in PPHW (20.1 ppm) fell within the lower part of the range of previously report arsenic concentrations in unpelletized poultry house waste. Arsenic concentrations in PBF, the source of which is less clear than for PPHW, were approximately a factor of 5 times lower than those in PPHW, with a mean concentration of 4.1 ppm. The pelletization and sale of these biological waste fertilizers present new pathways of exposure to arsenic in consumer populations who would otherwise not come into contact with these wastes. Arsenic exposures in humans resulting from use of these fertilizer pellets should be quantified to avoid potential unintended negative consequences of managing wastes through pelletization.     

Influences of human waste–based ectopic fermentation bed fillers on the soil properties and growth of Chinese pakchoi

The reuse of human wastes as biofertilizer resources offers a new option for meeting the growing demand for food and addressing poor soil productivity. Feces and black water are ubiquitous human wastes that usually require proper treatment, such as composting and anaerobic digestion, to remove potentially harmful substances before they can be applied as fertilizers. As an effective treatment technology for livestock farming wastes, the ectopic fermentation bed system (EFS) provides a new means of treating human waste and producing organic fertilizer from decomposed filler. Therefore, the objective of this study was to evaluate and compare the nutrient content and fertilizer potential of decomposed fillers obtained after EFS treatment of human feces and black water under different application conditions. The results showed that the application of fillers increased the yield of pakchoi by 3.60?29.32% and nutrient uptake by 8.09?83.45% compared to the CK, which could effectively promote the growth of pakchoi. This approach also improved the quality of pakchoi and enhanced soil fertility, and differences were observed in the effects of different kinds and application amounts of fillers. Soil EC was the soil property that had the greatest effect on the growth characteristics of pakchoi in this study. These findings help to better clarify the agronomic value of human wastes, but the effects of long-term filler application need to be further explored.

     

Drip-feed bioreactor for the treatment of concentrated wastes with minimal dilution

Avoiding substrate inhibition is a significant challenge in designing biological treatment systems for concentrated or toxic wastes. Substrate inhibition is commonly avoided by diluting the waste before treatment, however, dilution of a waste before treatment is not always feasible. In the case of radioactive mixed wastes and chemical warfare materiel (CWM), dilution presents regulatory and safety concerns. In this study, we investigated a "drip-feed" reactor configuration as an alternative approach for the biological treatment of concentrated waste streams with minimal dilution and complete containment. In the drip-feed reactor undiluted waste is slowly fed to biomass in a reactor at a rate sufficient to maintain activity, but at a low enough rate so that bacterial degradation maintains the reactor concentration below the toxic threshold. The reactor has no effluent, but rather fills as the undiluted waste is fed to the reactor, which has the advantage of preventing the release of hazardous material into the environment during treatment. Volatile releases are prevented with the use of condensers. The drip-feed bioreactor configuration was tested under aerobic conditions, at 25 degrees C, using a 10% acetonitrile feed solution. The treatment of acetonitrile to less than 0.1 mg l(-1) was achieved with a dilution factor of only 3.4. The acetonitrile degradation reaction was pH sensitive, where the optimal pH range for the biodegradation process was approximately between 6.5 and 7.1 and the biodegradation rate declined precipitously above pH 7.2. The applicability of the drip-feed reactor configuration to the treatment of mixed wastes and CWM is discussed.     

Laccase production by Phomopsis liquidambari B3 cultured with food waste and wheat straw as the main nitrogen and carbon sources

Food waste is the most difficult waste to manage because of the high treatment costs and the risk of environmental contamination. Wheat straw burning has become an increasingly discussed topic in recent years because of the air pollution it causes. However, food waste and wheat straw contain high amounts of nutrient elements; efficient utilization of these wastes can improve the environment by lessening airborne pollutant emission and the amount of waste that must be landfilled. It is well known that use of low-cost and abundant waste materials in microbial fermentations can reduce product costs. We aimed to use these resources while improving laccase production by the endophytic fungus Phomopsis liquidambari B3. We cultured P. liquidambari B3 in medium containing food waste and wheat straw as the main nitrogen and carbon sources, respectively. We optimized the fermentation conditions by response surface methodology (RSM), using a Box–Behnken design for RSM I and a central composite design for RSM II. Optimization resulted in an 11.07-fold (1.98-fold RSM I; 5.59-fold RSM II) increase in laccase yield compared with that before optimization. The model was validated by mathematical evaluations and by comparisons between predicted and experimental values. Under optimized conditions, 53.76% of lignin in wheat straw was degraded. By optimizing fermentation conditions and using multiple bioresources, laccase production by this fungus was increased. These results provide the foundation for future research and for scaled-up laccase production.

Implications:Food waste and wheat straw are waste products, but they could be bioresources if they were managed properly. In this work, we innovatively used a mixture of food waste and wheat straw as a substrate for the novel strain Phomopsis liquidambari B3 to produce laccase. This process, which provided the foundation for the subsequent research and for scaled-up laccase production, offers solutions for both rural and urban pollution problems: that is, it reduces the amount of waste material that needs to be disposed of by burning or dumping, and it also produces a valuable product.     

林可霉素菌渣与牛粪联合堆肥实验研究

抗生素菌渣因含有抗生素残留而成为一种较难处理的废弃物,不合理的处理方法极易造成环境污染和生态危害,同时也会造成资源浪费.为了探讨林可霉素菌渣堆肥化处理的可行性,设计了林可霉素菌渣与牛粪的联合堆肥实验.4个堆肥处理的林可霉素初始含量分别为1.35 mg/g(干重)、1.89 mg/g(干重)、3.52 mg/g(干重)和...     

三菌复合发酵提高厨余真蛋白含量的研究

为改善厨余发酵的品质,增加发酵后产品蛋白含量。采用三菌复合对厨余进行发酵,探讨了三菌复合的比例、接种量、发酵时间、初始pH值对发酵效果的影响,采用L9(34)正交实验对发酵条件进行优化,并对实验菌Lc和Ydy进行16S rRNA及18S rRNA分子鉴定。结果表明,最佳发酵条件为:菌剂配比(Lc∶Ydy∶S1)为3∶2∶1,接种量为0.15%,初始pH值为5.0,发酵时间为48 h。扩大实验结果表明,在最优发酵条件下,厨余经发酵后品质得到改善,真蛋白含量由发酵前的15.42%上升到发酵后的22.47%,增加率为45.80%;发酵后大肠菌群下降到30 cfu/g以下;乳酸菌及酵母菌数量分别为1.5×109 cfu/g和6.6×108 cfu/g。分子测序及鉴定结果表明,Lc为乳酸乳球菌,Ydy为热带假丝酵母菌。     

农业废弃物的资源化利用

我国的农业资源浪费和破坏现象十分严重,解决这一问题的根本途径是开展农业废弃物的资源化利用,它是农业可持续发展的重要方面。本文在分析了农业废弃物资源化利用的理论基础后,讨论了农业废弃物的主要资源化利用途径和支持与保障体系。     

西南地区某已封场非规范垃圾填埋场垃圾稳定化进程分析

以重庆某非规范填埋场为例,针对西南地区已封场非规范垃圾填埋场的稳定化进程进行了分析。按照场地布局选取4个采样点,在垃圾体上进行钻孔取样,分析不同深度的垃圾样pH值、有机质、含水率、生物可降解度以及垃圾样浸出液和填埋气组成以及各个指标随着填埋深度的变化规律,确定不同深度垃圾体的稳定化程度。结果表明,场内垃圾已呈现矿化垃圾特征;有机质、BDM、浸出液COD以及填埋气CH4含量等4个指标与填埋深度均较好地符合一级降解反应,可以预测垃圾体稳定化临界填埋深度。根据有机质、BDM、浸出液COD以及填埋气CH4含量等4个指标与填埋深度一级降解反应函数预测临界稳定化深度为15 m,与实测值判定的稳定化填埋深度相一致性。在对非规范垃圾填埋场场地利用过程中,需要先对未稳定的上层垃圾进行清理,并在已稳定的底层垃圾体上充填其他稳定介质后利用该地块。     

城市污水污泥固结体重金属浸出毒性及路用性能研究

城市污水污泥的重金属离子Pb、Zn超过国家固体废弃物排放最高允许值,属于危险废物。污水污泥的最佳出路是无害化处理,资源化利用,产业化发展。研究了以上海市污水污泥为原料,加入一定比例的固化剂和矿物掺合料使之固结,经养护满足路用强度性能,测试其固结体重金属离子浸出质量浓度亦满足国家固体废弃物排放标准,即污泥中的重金属离子得到有效的束缚和稳定固化,既解决了环境问题,又为污泥产业化发展开辟了新的途径。