生物炭输入对土壤污染物迁移行为的影响

重点综述了生物炭输入对土壤中污染物的吸附固持作用及生物有效性的影响,分析其作为土壤添加剂消减土壤污染风险的有效性,为生物炭在土壤中的应用研究提供依据。     

方舱传热试验方法研究

阐述了方舱传热系数的意义,介绍了美国材料与试验学会标准ASTM E 1925《刚性壁再配置结构的工程和设计标准规范》和GJB 2093《军用方舱通用试验方法》中方舱传热试验方法,从传热学理论和实际试验2方面对方舱传热试验进行了研究.结果表明,按照GJB 2093中热电偶的布置要求,在舱内整个立体空间内并不能真正达到温度...     

公共场所火灾伤员转运护理应急资源评估

为保障伤员生命与健康,提升火灾伤员救治率,该文研究公共场所火灾伤员转运护理应急资源评估方法。以火灾伤员转运护理应急资源需求分析为基础,从应急人员、应急设备、应急环境信息与应急管理四个方面出发,共选取15个评估指标,构建公共场所火灾伤员转运护理应急资源评估指标体系,根据各指标采集相关数据并对数据实施量纲标准化处理。构建基于层次分析法的评估模型,计算评估指标体系内各指标权重,引入类间权重与类内权重两个变量,分别表示专家学术与经验差异和专家个体逻辑性差异,提升指标权重的合理性;通过综合模糊评价将各指标分为“差、较差、一般、较好、好”五个等级。以某隧道火灾为对象采用该方法评估,验证了本方法的有效性。     

石油生物脱硫技术研究进展

生物脱硫技术由于具有条件温和、能耗低等优势受到人们关注。对生物脱硫新型微生物的筛选方向、生物脱硫技术中脱硫菌生长以及脱硫限制、传质限制等因素及其近期研究进展等方面进行了介绍,以期促进生物脱硫技术的研究深度。     

农地流转背景下地块规模对农户种粮投入影响分析

近年来粮食安全受到国家和社会的广泛关注,农地投入作为粮食生产的重要要素,是保障粮食稳定产出的前提。学者就农地规模对农户种粮投入的影响已进行了较多研究,但受农地流转的影响,土地要素更具多样化,土地规模与农户种粮投入的关系发生变化。随着农地流转在我国的快速发展,探析农地流转影响下土地规模对农户种粮投入影响的变化成为一个亟待研究的问题,对保障国家粮食安全具有重要意义。考虑到地块的异质性,本文基于山东、河南、安徽三个粮食主产省622户农户1 284个地块的粮食生产数据从村庄和农户两个层次控制了生产要素市场价格、地块要素等非主观因素,进行多层模型回归分析。结果表明,农地流转特征及地块特征对农户粮食生产单位面积投入有显著影响。地块规模和转入地占比对农地投入影响为负,转入地占比越大,地权稳定性越低,农户投入积极性受到挫伤越明显,在转入地上的投入减少。随着转入土地面积的增加,农户从事粮食生产的机会成本增大,使其有更强的动力增加种粮投入,地块规模的负向影响程度降低。基于分析结果,本文得出以下3点结论:(1)规模化经营有利于降低单位面积种粮成本;(2)农地流转发生时,地块规模对种粮投入的影响发生改变,成片规模化经营将成为我国粮食生产的必然趋势;(3)提高土地综合条件可以降低投入成本,并提高农户投入积极性。要保障国家粮食安全,需从降低种粮成本、提高农户收益着手,建议鼓励农村土地流转,推动粮食规模化生产,同时也要注重增加财政拨款,建设高标准粮田,强化高标准粮田的农业基础设施建设,完善田间配套工程。     

Insights into the electron transfer mechanisms of permanganate activation by carbon nanotube membrane for enhanced micropollutants degradation

● A CNT filter enabled effective KMnO₄ activation via facilitated electron transfer. ● Ultra-fast degradation of micropollutants were achieved in KMnO₄/CNT system. ● CNT mediated electron transfer process from electron-rich molecules to KMnO₄. ● Electron transfer dominated organic degradation. Numerous reagents have been proposed as electron sacrificers to induce the decomposition of permanganate (KMnO₄) by producing highly reactive Mn species for micropollutants degradation. However, this strategy can lead to low KMnO₄ utilization efficiency due to limitations associated with poor mass transport and high energy consumption. In the present study, we rationally designed a catalytic carbon nanotube (CNT) membrane for KMnO₄ activation toward enhanced degradation of micropollutants. The proposed flow-through system outperformed conventional batch reactor owing to the improved mass transfer via convection. Under optimal conditionals, a > 70% removal (equivalent to an oxidation flux of 2.43 mmol/(h·m²)) of 80 μmol/L sulfamethoxazole (SMX) solution can be achieved at single-pass mode. The experimental analysis and DFT studies verified that CNT could mediate direct electron transfer from organic molecules to KMnO₄, resulting in a high utilization efficiency of KMnO₄. Furthermore, the KMnO₄/CNT system had outstanding reusability and CNT could maintain a long-lasting reactivity, which served as a green strategy for the remediation of micropollutants in a sustainable manner. This study provides new insights into the electron transfer mechanisms and unveils the advantages of effective KMnO₄ utilization in the KMnO₄/CNT system for environmental remediation.     

Development of heat transfer and evaporation model of LNG covered by Hi-Ex foam

Natural gas is a kind of clean, efficient green energy source, which is used widely. Liquefied natural gas (LNG) is produced by cooling natural gas to −161 °C, at which it becomes the liquid. Once LNG was released, fire or explosion would happen when ignition source existed nearby. The high expansion foam (Hi-Ex foam) is believed to quickly blanket on the top of LNG spillage pool and warm the LNG vapor to lower the vapor cloud density at the ground level and raising vapor buoyancy. To identify the physical structure after it contacted with LN₂ and to develop heat transfer model, the small-scale field test with liquid nitrogen (LN₂) was designed. In experiment, three layers including frozen ice layer, frozen Hi-Ex layer and soft layer of Hi-Ex foam were observed at the steady state. By characterizing physical structure of the foam, formulas for calculating the surface of single foam bubble and counting foam film thickness were deduced. The micro heat transfer and evaporation model between cryogenic liquid and Hi-Ex foam was established. Indicating the physical structure of the frozen ice layer, there were a certain number of icicles below it. The heat transfer and evaporation mathematical model between the frozen ice layer and LNG was derived. Combining models above with the heat transfer between LNG, ground and cofferdam, the heat transfer and evaporation mathematical model of LNG covered by Hi-Ex foam was developed eventually. Finally, LN₂ evaporation rate calculated by this model was compared with the measured evaporation rate. The calculated results are 1.2–2.1 times of experimental results, which were acceptable in engineering and proved the model was reliable.     

Study of the performance of a coolant mixed with an Al2O3/SiC nanomaterial in an engine radiator

One of the important components of a car to control the temperature of a car's engine is the radiator. To increase the heat absorption capacity of the coolant/fluid used in the radiator with minimum pumping power, innovative fluids called nanofluids have become the main area of research these days. Therefore, with the development of new technologies in the field of “nano-materials” and “nano-fluids,” the physical and chemical properties of coolant/fluid can be improved which in turn improves the radiator and engine efficiency, and reduces radiator weight and size. In this article, the heat transfer by forced convection in nanofluids based on Al₂O₃ and SiC was studied experimentally and compared to that of base fluid in an automotive radiator. The nanofluid is mixed with ethylene glycol and the fluid is prepared by the sonication method. The nanofluids were prepared by varying the nanomaterials and the amounts of nanomaterials in the base fluid and their heat transfer performance in the radiator was analyzed using ANSYS FLUENT software. Approximately 15% and 12% increase in radiator efficiency by using Al₂O₃ mixed nanofluid and SiC mixed nanofluid, respectively.     

关天经济区农户农地流转行为研究

农地流转是现阶段实现农地规模经营的必经之路。本文基于关天经济区622份调查问卷,建立了农地流转的农户模型,利用Heckman两阶段模型研究了交易成本认知和农户禀赋对农户参与农地流转(转出)、农地流转率的影响。研究结果表明:(1)关天经济区农户参与农地流转的积极性不高,样本农户参与农地流转的仅为23%,农地流转率均值为11%;(2)流转价格了解程度、农地流转组织形式、农地流转合约期限和对外交通便利情况影响农户是否参与农地流转决策,而农地流转率仅受流转价格了解程度和农地流转契约形式影响;(3)劳动力和土地禀赋正向影响农户转出土地,农地流转率随农业生产能力增强而降低;(4)文化程度与农户是否参与农地流转、农地流转率呈现显著的负相关关系,与天水的农户相比,关中地区的农户更倾向于参与农地流转。因此,要促进农户参与农地流转、提升农地流转率,首先要加强农地流转政策的宣传力度,提高农户整体认知水平,增强农户农地流转政策的理解程度和接受能力;其次,深化农村土地产权改革,加快农地确权颁证,提升农户产权的稳定性和可预期性;再次,建立健全农地流转市场,完善市场在农地流转过程中的信号生成机制和传递功能,降低农地流转过程中的交易成本;第四,采取相应的激励政策提高农户土地、劳动力的利用程度,提升农户农业生产能力,避免农户在农地流转市场中的逆向选择行为;最后,建立有效的农地"经营权退出机制",将束缚在农业生产上的低效劳动力和土地释放出来,实现资源的最优化配置。     

基于生态足迹的武汉城市圈生态承载力评价和生态补偿研究

在推进新型城镇化和生态建设的背景下,客观定量评价区域生态环境状态,是当前我国生态建设重要而紧迫的任务之一。高密度的人类活动会对自然生态系统产生超负荷的压力,通过生态承载力的分析能够定量测度这种状况,为区域可持续发展提供借鉴意义。基于生态足迹模型,计算了2008年和2013年武汉城市圈各县域单元的生态足迹/承载力,并进行了时空变化分析。研究发现武汉城市圈各县域单元的生态足迹和生态承载力在空间上存在显著的差异性,生态足迹逐年增加,生态承载力的变化相对较小,出现两级分化的现象。根据生态足迹/承载力进行跨区县生态补偿测算,得到2008年和2013年武汉城市圈48个县域的转移支付情况,表明如果运用财政转移支付的手段,整个区域能够达到生态系统供给和需求动态平衡的目标,缓解武汉城市圈的生态压力,实现武汉城市圈的可持续发展。