火电机组循环冷却水节能自动控制系统

针对火电厂水冷机组循环冷却水系统．通过试验研究和理论分析相结合的方法．搭建科学准确的教学模型．结合电厂DCS系统的控制功能,建立独立模块,实现集计算、控制、统计及实时监测等功能于一体的节能优化自动控制系统．以达到节能降耗的目的。     

“资源循环科学与工程”新专业成立

据悉,近日,全国"资源循环科学与工程"专业建设研讨会在南开大学省身楼隆重召开,教育部公布成立"资源循环科学与工程"新专业的东北大学、山东大学、西安建筑科技大学、山东理工大学、长春工业大学、福建师范大学、湖南师范大学等单位代表出席了会议,朱坦教授率环境科学与工程学院十余位相关教师出席会议。会上,各高校参会代表在交流本院校专业学科背景、专业建设基础、专业培养目标、教学计划内容及课程设置等内容的基础上,就资源循环科学与工程专业的大学本培养方案;课程设置与教材建设;办学特点、以及各自在专     

节能小知识

1.安装太阳能热水器。夏季水温可直接使用,冬季可接入锅炉加热至需要的水温。据已采用此项技术的单位统计,至少可节能20%至30%。2.实行垃圾分检。将纸张、瓶罐、金属、有机物分检,分别回收处理或就地转化为沼气、肥料、生物能源等以循环利用。饭店可以因地制宜加入大循环或利用小循环。回收1吨废纸可以少砍17棵大树,生产800kg好纸;回收1t玻璃可节约600kg矿砂和100kg燃油;回收1吨塑料可节约600～800kg石油。     

自然循环污水处理技术的应用与创新

以示范工程为契机,引进、消化吸收国际先进污水处理技术和设计理念。该技术作为一项小型生活污水处理先进技术,具有较好的推广应用价值和前景,对于出水水质要求高、气候条件恶劣的地区应用优势明显,在低温、青藏高原地区较其它工艺技术更能适应。     

海洋中丙烯酸的研究进展

丙烯酸是海洋中的短链脂肪酸,是海洋中主要含硫化合物DMSP(dimethylsulfoniopropionate,β-二甲基巯基丙酸内盐)裂解的产物之一。本文综述了海洋中丙烯酸的来源、性质、在海洋中的作用以及海水中丙烯酸的测定方法。通过观测海水中丙烯酸的含量、分布及生物地球化学循环过程,有助于了解丙烯酸对海洋生态系统碳循环和硫循环的贡献。并对海洋中丙烯酸的进一步研究提出了展望。     

如何建立多层次HSE管理体系的PDCA循环模式

PDCA循环模式是HSE管理体系运行的最基本方式,也是实现体系绩效螺旋式上升的重要手段.在体系运行的过程中,经过PDCA等各个环节以及各环节涉及到的诸多要素的不断发展与完善,体系的目标与方针得以实现.从管理体系实际运行的角度来看,整个体系运行过程中的PDCA循环又可以分为以下层次:单要素间某几个管理方面的相互影响与作用;几个要素之间形成的PDCA循环;大部分要素(关键要素)之间的作用;整个体系的PDCA循环.这几层次的循环模式也是相互交叉相互作用的.现以表1所涉及的工作为例,探讨这几个层次PDCA循环的相关性.     

种植苜蓿草的生态环境效益和经济效益分析——苜蓿草在台安县洪家农牧场种植实验

2004年台安县洪家农牧场引进加拿大优质苜蓿草进行种植实验.通过清种、林地间作和不种苜蓿草对比实验,对土壤速效氮、速效磷、速效钾、有机质、PH值、含水量进行分析,得出种植苜蓿草所产生的生态环境效益和经济效益.此项实验结论说明,紫色苜蓿是牧草之王,可促进养殖业的发展,对改善生态环境,防止土壤沙化和水土流失,改善农业结构,实现生态良性循环起到积极的促进作用,对改善生态环境起到了良好的示范作用.     

空调系统冷冻水循环水泵变频运行的变温差控制

在分析空调系统变流量运行调节的基础上,提出了变温差控制并给出了控制方案。变温差控制过程不仅具有负反馈,而且具有正反馈,能较好的适应空调负荷的变化。比较分析了变温差控制、定温差控制、定压差控制的节能性,变温差控制的节能潜力最大,是一种最佳控制方式。     

Impacts of wastewater sludge amendments in restoring nitrogen cycle in p-nitrophenol contaminated soil

The possible impacts on nitrogen-cycle in a p-nitrophenol (PNP) polluted soil and the e ectiveness of wastewater sludge amendments in restoring nitrification potential and urease activity were evaluated by an incubation study. The results indicated that PNP at 250 mg/kg soil inhibited urease activity, nitrification potential, arginine ammonification rate and heterotrophic bacteria counts to some extents. After exposure to PNP, the nitrification potential of the tested soil was dramatically reduced to zero over a period of 30 days. Based on the findings, nitrification potential was postulated as a simple biochemical indicator for PNP pollution in soils. Nitrogen-cycling processes in soils responded positively to the applications of wastewater sludges. A sludge application rate of 200 tons/ha was su cient for successful biostimulation of these nitrogen processes. The microbial activities in sludge-amended, heavy PNP-polluted soils seemed to recover after 30–45 days, indicating the e ectiveness of sludge as a useful soil amendment.     

Nitrogen cycle of a typical Suaeda salsa marsh ecosystem in the Yellow River estuary

The nitrogen (N) biological cycle of the Suaeda salsa marsh ecosystem in the Yellow River estuary was studied during 2008 to 2009. Results showed that soil N had significant seasonal fluctuations and vertical distribution. The N/P ratio (15.73±1.77) of S. salsa was less than 16, indicating that plant growth was limited by both N and P. The N absorption coefficient of S. salsa was very low (0.007), while the N utilization and cycle coefficients were high (0.824 and 0.331, respectively). The N turnover among compartments of S. salsa marsh showed that N uptake from aboveground parts and roots were 2.539 and 0.622 g/m2, respectively. The N translocation from aboveground parts to roots and from roots to soil were 2.042 and 0.076 g/m2, respectively. The N translocation from aboveground living bodies to litter was 0.497 g/m2, the annual N return from litter to soil was far less than 0.368 g/m2, and the net N mineralization in topsoil during the growing season was 0.033 g/m2. N was an important limiting factor in S. salsa marsh, and the ecosystem was classified as unstable and vulnerable. S. salsa was seemingly well adapted to the low-nutrient status and vulnerable habitat, and the nutrient enrichment due to N import from the Yellow River estuary would be a potential threat to the S. salsa marsh. Excessive nutrient loading might favor invasive species and induce severe long-term degradation of the ecosystem if human intervention measures were not taken. The N quantitative relationships determined in our study might provide a scientific basis for the establishment of effective measures.