Zeolite powder addition to improve the performance of submerged gravitation-filtration membrane bioreactor

In this study, the effect of zeolite powder addition on submerged membrane bioreactor （SMBR） on membrane permeability, and the removals for COD, NH3-N, TN were investigated. Through the parallel operation of control and test systems, it was found that the zeolite powder addition could alleviate the ultra-filtration membrane fouling and enhance the membrane permeability. On the basis of experimental investigations, a concept of ＂protection coating layer＂ was proposed to illustrate the phenomenon of UF membrane fouling. In addition, the removal for COD in test system was more stable, a little higher compared to the control system. Due to the combination of nitrification and ion exchange, a more excellent removal for NH3-N in test system was obtained regardless of influent NH3-N loading rate. It was also found that a mean 25% higher TN removal took place in the test system, and ion exchange and simultaneous nitrification and de-nitrification were analyzed to be main factors. During the stable operation period, the SOURs of test zeolite powder added sludge and control activated sludge were measured to be 75 mgO2/（gMLVSS, h） and 24 mgO2/（gMLVSS, h） respectively, it meant that the zeolite powder addition could enhance the microorganism activity significantly.

Ultrafiltration with in-line coagulation for the removal of natural humic acid and membrane fouling mechanism

Experimental and theoretical analysis were made on the natural humic acid removal and the membrane fouling of ultrafiltration （UF） with in-line coagulation. The results showed dissolved organic carbon （DOC） and UV254 removals by the UF with in-line coagulation at pH 7 were increased from 28% to 53% and 40% to 78% in comparison with direct UF treatment respectively. At the same time, the analysis of high performance liquid chromatography showed that UF with coagulation had significant improvement of removal of humic acid with molecular weights less than 6000 Da in particular. Compared to direct UF, the in-line coagulation UF also kept more constant permeate flux and very slight increase oftransmembrane pressure during a filtration circle. Two typical membrane fouling models were used by inducing two coefficients Kc and Kp corresponding to cake filtration model and pore narrowing model respectively. It was found that membrane fouling by pore-narrowing effect was effectively alleviated and that by cake-filtration was much decreased by in-line coagulation. Under the condition of coagulation prior to ultrafiltration at pH 7, the cake layer formed on the membrane surface became thicker, but the membrane filtration resistance was lower than that at pH 5 with the extension of operation time.

Performance Assessment of Heat Exchangers for Process Heat Integration

Pinch Analysis is an attractive solution for reduction of thermal energy costs in thermo-chemical industries.In this approach,maximum internally recoverable heat is determined and a heat exchange network is designed to meet the recovery targets.The thermal performance of a heat exchanger over its lifetime is however a concern to industries.Thermal performance of a heat exchanger is affected by many factors which include the physical prop-erties of the shell and tube materials,and the chemical properties of the heat transferfluid.In this study,thermal performance of shell and tube heat exchangers designed to meet heat recovery targets in a Pinch Analysis study is simulated.The aim of this paper is to present predictions of thermal performances of shell and tube heat exchan-gers with different heat transferfluids and geometries as they undergo fouling degradation.Engineering approaches based on thermodynamic analysis,heat balance and Kern Design equations,as well as what-if simu-lation modeling are used in this work.Shell and tube heat exchangers were designed to meet internal heat recov-ery targets for three process plants,A,B and C.These targets were published in a separate paper.The effects of degradation of the tubes-due to incremental growth of fouling resistance-on thermal performance of the exchan-ger were simulated using Visual Basic Analysis(VBA).Overall,it was found that growth in fouling reduces ther-mal efficiency of shell and tube heat exchangers with an exponential relationship.An increase of 100%of fouling resistance leads to an average reduction of 0.37%heat transfer.Higher values of logarithmic mean temperature difference(LMTD)and higher ratios of external diameter to internal diameter of the exchanger tubes amplify the effect of fouling growth on thermal performance of the exchangers.The results of this work can be applied in pinch analysis,during design of heat exchangers to meet the internal heat recovery targets,especially in predicting how fouling growth can affect these targets.This can also be useful in helping operators of shell and tube heat exchangers to determine cleaning intervals of the exchangers to avoid heat transfer loss.

Gas Turbine Performance Optimization Using Compressor Online Water Washing Technique

The ability to predict the behaviour of a gas turbine engine and optimize its performance is critical in eco-nomic, thermal and condition monitoring studies. Having identified fouling as one of the major sources of compressor and therefore gas turbine deterioration, a computer-based engine model was developed to optimize the performance of gas turbines. The paper thus presents an analysis of compressor hand cleaning, on and offline compressor washing to actualize the technique using a computer program in Visual Basic programming language with data collected over a period of fifteen weeks for 2 gas turbine plants GT1 and GT2. The results of the data collected, when collated, shows that after washing, the overall operational efficiency changed from 39.2% to 46.25%. To optimize the performance of gas turbine engines, it is therefore recommended that operators should perform a combination of compressor hand cleaning, offline and online washing simultaneously.

氧化石墨烯界面调控纳滤膜制备及性能研究

为提高传统聚酰胺纳滤膜渗透性能和抗污染性能,文章以聚砜(PSF)超滤膜为基材,以哌嗪、均苯三甲酰氯为水相和有机相单体,引入氧化石墨烯(GO)作为亲水改性材料,通过界面聚合法制备氧化石墨烯复合纳滤膜(GO-PA-PSF膜),研究GO占比对膜表面形貌、化学结构及分离性能的影响。结果表明,当GO质量分数为0.01%时,GO-PA-PSF膜表面开始出现褶皱,膜表面粗糙度、亲水性和负电性增强,其渗透通量为50.47 L/(m^(2)·h),对Na_(2)SO_(4)的截留率为98.14%,在30 h脱盐试验中保持良好的稳定性,对3种模型污染物的抗污染性能有所提升。

基于甘蔗渣多孔碳的超疏水棉织物制备及其性能

针对目前超疏水材料制备原料成本较高的问题,以农林废弃物甘蔗渣为主要原料采用高温炭化活化法制备了多孔碳,并将甘蔗渣基多孔碳(BPC)与低表面能物质聚二甲基硅氧烷(PDMS)结合构筑超疏水功能棉织物。研究了活化温度和活化剂用量对BPC结构和微观形貌的影响,评价了BPC和PDMS质量分数对整理棉织物疏水性能的影响。结果表明:当活化温度为700℃,且BPC和活化剂质量比为1∶4时,制备的BPC比表面积达到1 614.25 m^(2)/g,且石墨化程度较高,表面具有粗糙结构且微孔分布最多;PDMS为棉织物提供低表面能的同时,能够将BPC牢固黏结在棉织物表面;当PDMS质量分数为3%,BPC质量分数为0.2%时,所构筑的棉织物超疏水性能较好,静态水滴接触角可达162.2°,实现了超疏水棉织物的优异自清洁、防水抗污性能。

基于PLEIK模型的岩溶地下水防污性能评价——以贵阳市汪家大井泉域为例

岩溶地下水资源是中国西南地区经济发展的重要基础。对岩溶地下水进行防污性能评价是合理开发及保护当地地下水资源的有效方法。汪家大井现为贵阳市东郊水厂取水地,是区域内重要的供水水源,对其进行地下水防污性能评价有助于保障居民饮用水水源安全。通过构建研究区PLEIK模型,在考虑保护性盖层(P)、土地利用类型(L)、表层岩溶带发育程度(E)、补给类型(I)及岩溶网络发育程度(K)5个评价因子的基础上,对汪家大井泉域岩溶地下水防污性能进行定量评价。结果表明,研究区内地下水防污性能以较好和中等的区域为主,分别占总面积的23.69%和42.11%;防污性能较差和好的区域次之,分别占总面积的18.54%和15.53%;防污性能差的区域最少,约占总面积的0.13%;表层岩溶带、含水层岩溶网络及土地利用类型是影响该区域岩溶地下水防污性能的主要因素。其研究结果可为该地区地下水环境保护及污染防治提供一定的参考。

两性离子聚合物接枝改性有机膜亲水性的研究进展

膜分离过程被普遍存在的膜污染问题所困扰。两性离子聚合物是在同一分子中含有阴离子和阳离子单元的代表性材料,由于其超亲水性、化学稳定性和优异的防污能力,在生物医学和分离材料等领域受到了广泛关注。将两性离子分类,综述了将两性离子材料结合到膜表面以提高膜抗污染性能的常见方法,包括引发剂引发、等离子体引发、紫外诱导引发等。最后对两性离子改性高分子膜未来的发展进行了简单的评价和展望。

基于性能监测的聚合冷凝器结垢RUL预测

针对聚合反应气相冷凝过程易造成换热器结垢的问题,基于性能监测,对聚合冷凝器结垢剩余使用寿命(RUL)预测方法建立了在线监测系统。该系统利用实时采集的聚合冷凝器运行参数,对其相变过程性能参数进行计算和监测,并基于性能指标对其低劣化趋势进行定量化管理,对RUL进行预测。若结垢RUL指标达到阈值,则采用侧线冲洗的方法,对管板积聚污垢进行冲洗,从而有效地延长大修周期。最后,通过在企业实际工程中的应用,验证了系统的有效性和实用性。研究结果表明,应用基于性能监测和结垢RUL预测方法可以提高冷凝器的性能指标,降低能耗,优化冲洗效果,减少维修和运营成本,从而提高生产效率。

新乐市地下水防污性能评价

【目的】新乐市地下水资源丰富,为保护地下水资源,保证人民饮用水安全,研究地下水防污性能评价具有重要意义。【方法】采用DRASTIC评价方法,选取反映水文地质条件的7个参数:地下水埋深、含水层净补给量、含水层岩性、土壤介质类型、地形坡度、包气带岩性及含水层水力传导系数等对新乐市地下水防污性能进行评价。【结果】新乐市分为防污性能较好区、防污性能中等区和防污性能较差区,该区域划分较为客观,符合现状。【结论】为各级决策部门的合理规划,保护地下水资源提供简单明了的科学依据。

防污运动鞋用超细纤维合成革生产方法与关键技术

超细纤维合成革类似于天然皮革,外观、性能与天然皮革高度相似,拥有良好的发展潜力与广阔的应用前景,但耐磨性与防污性相对较差。为有效优化运动鞋防污性能,本文针对性解析了运动鞋用超细纤维合成革生产方法与关键技术。结果表明,防污运动鞋用超细纤维合成革与天然皮革外观、手感、柔软度、耐褶皱性相接近,而透水汽性优于聚氨酯人造革等常用帮面材料;防污运动鞋用超细纤维合成革耐磨性、耐折性、撕裂性、拉伸性等力学性能优越,可满足防污运动鞋帮面制作材料要求;防污运动鞋用超细纤维合成革防污性能优异,可确保运动鞋兼具防污性与防水透湿性。

无杆采油井筒用防垢剂性能研究与应用

为达到提高油气田采收率的目的,在油气田开发的中后期,采用注水的开发方式,但此种开发方式会导致无杆采油井筒出现结垢问题,这将给油气田的生产带来很多危害。针对结垢问题,目前主要是通过加入防垢剂来防止垢物的形成。基于此,选用马来酸酐(MA)和丙烯酸(AA)为单体,过硫酸钾为引发剂,过氧化氢为催化剂,采用水溶液聚合的方法合成目标产物HLM,考察防垢剂加量、Ca^(2+)质量浓度、体系温度和pH以及恒温时间对防垢率的影响。实验结果表明:随着Ca^(2+)浓度的增加、体系温度的上升、恒温时间的延长、pH值的增大,防垢剂HLM的防垢率有所下降,但下降的程度不同。当体系温度在70℃、恒温时间为10 h、体系pH为7时,防垢剂HLM具有较好的防垢性能。现场应用结果表明防垢剂HLM具备优异的防垢效果。

电化学膜生物反应器处理污水性能提升策略及研究现状

针对膜生物反应器(membrane bioreactor,MBR)处理污水时存在脱氮效果差、运行能耗高和膜污染严重问题以及微生物燃料电池(microbial fuel cell,MFC)存在出水质量差、所产电能未被有效利用的技术缺陷,电化学膜生物反应器(electrochemistry membrane bioreactor,EMBR)耦合MBR和MFC处理技术,可弥补两者技术缺点,能够实现高效去除污染物的同时减缓膜污染,具有广阔的应用前景。根据EMBR结构特点进行分类;从组成材料选取和运行参数优化角度重点阐述提升EMBR污水处理性能的策略;并从污染物去除、产电性能和膜污染减缓方面详细阐述了EMBR在污水处理中的研究现状;最后指出EMBR处理污水存在的问题及不足,并从新材料的开发与使用、装置规模、膜污染减缓机制、微生物群落结构组成及代谢机理等方面提出建议和展望,以期为EMBR处理技术实现规模化应用提供科学依据。

铝制板式换热器表面喷淋结垢行为研究

近年来换热器中闭式循环水系统不断发展,在夏季高温换热过程中,其外部喷淋系统易引起换热器结垢及腐蚀。为了研究喷淋工作溶液在不同pH值及喷淋状态下对换热器的结垢及腐蚀影响情况,设计了浸泡实验、间隔滴定法等实验方法,模拟实际工作环境,通过样板微观表面形貌观察、质量变化、电化学性能测试等表征方法进一步明确了换热器结垢机理。实验结果表明:在短周期加热滴定实验下,pH=5的模拟溶液在动态环境下容易发生反应,在扁管位置易结垢;在浸泡实验、长周期加热滴定实验下,模拟溶液处于相对静态条件,实验样品不易出现结垢,丰富了板式换热器结垢情况的相关研究,为以后板式换热器结垢及腐蚀防护提供了有力依据。

抗污型有机硅改性聚氨酯丙烯酸酯的合成及性能

为解决聚氨酯丙烯酸酯抗污性能差的问题,将含端羟基的聚硅氧烷分子结构引入到由季戊四醇三丙烯酸酯(PETA)和异佛尔酮二异氰酸酯(IPDI)制备的聚氨酯丙烯酸酯的合成中,得到了一种可紫外光固化并具有抗污性能的有机硅改性聚氨酯丙烯酸酯。有机硅改性聚氨酯丙烯酸酯的最佳合成条件:羟基与异氰酸基的摩尔比为1.2∶1,端羟基聚二甲基硅氧烷(HO—PDMS—OH)的质量分数为5%,催化剂二丁基二月桂酸锡(DBTDL)的质量分数为0.1%,阻聚剂对羟基苯甲醚(MEHQ)的质量分数为0.2%,反应温度为80℃,反应时间为3 h。对以其制备的UV固化涂膜进行了红外光谱(FT IR)和热重分析(TG)表征及性能测试,结果表明,该树脂制备的涂膜具有优良的抗污性能(较高接触角、较低滚动角以及良好的油墨(油性记号笔)收缩性)、吸水率低、硬度高、附着力好、热稳定佳等。

新型超支化改性氟硅聚氨酯防水涂料制备及性能研究

本研究将一系列超支化聚缩水甘油醚(HPG)合成得到水性超支化氟硅聚氨酯,加入HPG接枝的氧化石墨烯制备有机-纳米杂化防水涂料(HGX),并对其性能进行了测试。研究表明,加入高支化代数和高主链分子量的HPG改性的氧化石墨烯后,HGX涂层的疏水性、防水性能以及防污性能显著提高,可以作为高效、环保的海洋防水防护涂料。

半封螺杆变频盐水机组节能分析及验证

根据江森自控变频盐水机组的设计及应用特点,分析其部分负荷性能的影响因素。变转速控制压缩机实现部分负荷下仍具有高的绝热效率,经济器也可以始终保持运行,从而克服滑阀调节机组存在的缺点,保证机组在部分负荷下高效率运行。经过实际测试验证,变转速控制的部分负荷性能优势明显。另外,测试过程中,发现污垢系数对机组性能影响显著,在设计过程中需要特别考虑。

UiO-66/薄膜复合聚酰胺反渗透膜的制备及性能研究

薄膜复合聚酰胺反渗透膜是应用最广泛的反渗透膜材料之一。本文选择UiO-66作为反渗透膜的改性材料,引入界面聚合有机溶液中制备成反渗透膜并研究了其渗透性能、抗污染性能和耐氯化性能,结果表明,UiO-66的添加可有效降低膜的活性层厚度,从而缩短水通道距离、降低水的跨膜阻力。UiO-66与聚酰胺之间形成了-N-C=O-和-N-C=O-OH基团,可以抑制亚胺与氯的取代,使膜不易受到氯的侵蚀,膜的耐氯性能提高了94.4%。UiO-66的引入使膜的亲水性增强,表面更加光滑,水中污染物与膜表面的相互作用减弱,与空白膜相比,复合膜的抗污染性能提高了35.8%。UiO-66的使用可为今后高性能反渗透膜的制备提供技术基础,提高膜的脱盐性能、抗污染性能和耐氯化性能,有望进一步降低反渗透膜的运行成本。

掺加纳米级藻苔杀除剂的抗污混凝土性能研究

针对目前市政工程混凝土表面受藻类侵害污染的问题,采用纳米级银离子藻苔杀除剂配制抗污混凝土,研究其对混凝土的工作性能、力学性能及耐久性能的影响;采用试验藻类生长情况方法,以荧光相对值来表征混凝土的抗藻性能,即抗污性能,最大荧光值越低,混凝土抗污性能越好。研究表明:掺加纳米级藻苔杀除剂后,混凝土的工作性能表现出一定程度的降低;不同掺量及不同方式掺入杀除剂对混凝土抗压强度影响不明显,对混凝土抗氯离子渗透性能影响较大;随着杀除剂掺量的增加,混凝土抗污性能显著提高,以磁力40分钟掺入方式效果最好;混凝土微生物污染最严重的区域位于干湿循环区。

纳滤过程的污染问题及纳滤膜性能的影响因素

介绍了纳滤膜的定义及分类 ,并对纳滤过程中污染现象的影响因素 ,如温度、浓差极化、料液浓度、pH值、流速和流型等作了详细的综述 ,指出了 4种主要的减轻污染的方法 .这 4种方法分别是膜清洗、改变物料的性质、改变操作方式及膜面改性 .同时对纳滤膜渗透及截留性能的影响因素 ,如操作压力、操作时间、料液流速等进行了较详细的阐述 .