Oxidative Desulfurization of Non-hydrotreated Kerosene Using Hydrogen Peroxide and Acetic Acid

The oxidative desulfurization of a real refinery feedstock (i.e.,non-hydrotreated kerosene with total sulfur mass content of 0.16%) with a mixture of hydrogen peroxide and acetic acid was studied.The influences of various operating parameters including reaction temperature (T),acid to sulfur molar ratio (nacid/nS),and oxidant to sulfur molar ratio (nO/nS) on the sulfur removal of kerosene were investigated.The results revealed that an increase in the reaction temperature (T) and nacid/nS enhances the sulfur removal.Moreover,there is an optimum nO/nS related to the reaction temperature and the best sulfur removal could be obtained at nO/nS=8 and 23 for the reaction temperatures of 25 and 60°C,respectively.The maximum observed sulfur removal in the present oxidative desulfurization system was 83.3%.

Oxidative Desulfurization of Diesel Fuel with Hydrogen Peroxide Using Na_2WO_4 as Catalyst

Oxidative desulfurization was performed on Na2WO4 catalyst in the presence of hydrogen peroxide and acetic acid under mild reaction conditions (atmospheric pressure and temperature range of 293—343 K). Different organic compounds including benzothiophene (BT), dibenzothiophene (DBT), 4, 6-dimethyl dibenzothiophene (4, 6-DMDBT) were used to investigate the reactivity of this catalyst, and the effect of various parameters, such as temperature, solvents and the amount of oxidant reagent used in oxidative desulfurization reaction, was also examined. The results showed that the Na2WO4- H2O2 system was very effective for oxidative desulfurization, and the oxidation of BT, DBT and 4, 6-DMDBT was influ-enced by different parameters.

Catalytic Desulfurization of n-Butyl-sulfide over HZSM-5 Zeolite in the Presence of a Hydrogen Provider

The catalytic desulfurization of a model organic sulfurous compound n-butyl-sulfide in a fixed bed microreactor is studied in the presence of catalyst and a hydrogen provider. The experimental results show that the appropriate reaction conditions are： a mixed catalyst of HZSM-5 zeolite and Co-Mo/Al2O3-TiO2, a reaction temperature of 300℃, atmosphere pressure, a feed speed of 50 mL/h and a mass hourly space velocity of 3.0 h^-1 A higher catalytic property and desulfurization efficiency of the mixed catalyst of HZSM-5 zeolite and Co-Mo/Al2O3-TiO2 is achieved. The adsorption and desulfurization efficiency of the FCC gasoline from Shenghua Refinery, which is affiliated to China University of Petroleum （East China）, is 53.0 %.

Reductive Desulfurization of Thioamides to Amines by Catalytic Hydrogen Transfer Reaction

Introduction Reductive desulfurization of thioamides to amines is one of the methods to prepare amines and is generally achieved by a) Zn in acid, b) sodium or aluminum amal- gams, c) lithium alumminium hydride, d) Raney Ni and e) electrolytic reduction. These methods are not very convenient to be operated and some need more complex instrument. Here is reported the reductive desulfurization of thioamides to amines by catalytic hydrogen transfer reaction(CHT).

Ambient temperature desulfurizer of nano-ZnO modified with cerium

The compound nano-ZnO modified with Ce was prepared by homogeneous precipitation.IR,XRD and dynamic experiments show that the crystal size of nano-ZnO desulfurizer is decreased after being modified with Ce and its desulfurization activities are improved greatly.When calcined at 270 ℃,Ce distributes evenly on the ZnO particle surface as amorphous state oxides,and the amorphous ZnO·H2O also exists;when the calcining temperature is 570 ℃,the crystal CeO2 separates out and the amorphous structure of zinc oxide disappears,at the same time,the crystal is perfect and its size increases,but the desulfurization activities decrease.The desulfurization product of nano-ZnO modified with Ce was analyzed with XPS.The results show that the adsorption compound of HS,S and ZnS exists on the surface of the desulfurizer.

煤层H_(2)S与煤脱硫协同治理研究

为研究煤层H_(2)S与煤脱硫的协同治理,自制装置对复配碱液进行H_(2)S吸收和煤脱硫试验。采用离子色谱法、X射线光电子能谱、形态硫测试对吸收液和煤样进行表征,分析协同治理机理,利用响应面法分析各因素对H_(2)S吸收和煤脱硫的影响程度。结果显示:单一碱液均可吸收H_(2)S,但脱硫效果微弱;添加NaClO后,协同治理效果显著且能避免H_(2)S二次逸散,其中NaOH+NaClO协同治理效果最优。在反应后,H_(2)S及煤中低价态硫噻吩、硫醇和硫醚减少,吸收液中SO_(4)^(2-)及煤中高价态硫(亚)砜增加,表明NaOH为元素硫歧化提供碱性条件,元素硫继而被NaClO氧化。NaOH质量浓度对H_(2)S吸收影响最大,NaClO质量浓度对煤脱硫影响最大,NaOH和NaClO交互对煤脱硫与H_(2)S吸收影响显著。利用Design-Expert软件确定最佳参数:NaOH质量浓度为54 g/L、NaClO质量浓度为54 g/L、温度为21.4℃。

泄漏硫化氢干法应急处置安全性及工艺研究

目的在高含硫油气井和炼化厂脱硫装置生产过程中存在硫化氢(H_(2)S)泄漏的风险,而以物理稀释为主的应急处置方法效率低,影响应急救援。拟采用气体捕集与干法脱硫相结合的工艺进行泄漏H_(2)S的处置,并对泄漏气体中引入空气是否会影响干法脱硫的安全性和脱硫剂的性能开展实验研究。方法通过模拟泄漏H_(2)S干法处理流程,对比测试了活性炭、氧化铁和氧化锌等不同类型干法脱硫剂的穿透硫容和床层温升,优选出性能更好的脱硫剂。以优选脱硫剂为研究对象,考查在不同H_(2)S含量的条件下,空速和空气含量对其温升、穿透硫容、脱硫精度和副反应的影响。结果从8种不同厂家提供的氧化铁脱硫剂中优选出穿透硫容最高的3#脱硫剂,在原粒度模拟工况条件下,其穿透硫容可达到18.2%;脱硫剂床层温升随着H_(2)S含量的增加而升高,随着空速和空气含量的增大,脱硫剂床层温升呈现先迅速升高后趋于平稳甚至略有下降的趋势,最高不超过40℃;当空气体积分数超过25%时,脱硫剂穿透硫容提高约50%,空速与穿透硫容呈明显负相关性;当空速低于1000h-1时,穿透硫容超过25%,空气含量对脱硫精度和副反应无影响;在H_(2)S穿透前和空速低于2000h-1的条件下,没有生成副产物二氧化硫(SO_(2))。结论采用干法脱硫工艺对泄漏H_(2)S进行处理,会同时发生脱硫和再生过程,床层会产生一定的温升,没有生成副产物SO_(2),具有较高的安全性。空气的加入提升了脱硫剂的硫容性能,在对泄漏H_(2)S进行干法应急处置时空气体积分数应大于25%,空速应低于1000h-1。

载体对MoP催化剂HDN、HDS和HYD性能的影响

探讨了TiO2、SiO2(B)、SiO2(H)和γAl2O34种载体对负载型MoP催化剂加氢精制活性的影响。采用XRD、NH3TPD和TG DTG手段对MoP催化剂进行了表征。以噻吩、吡啶和环己烯为模型化合物,用高压连续微反装置评价MoP催化剂的加氢脱氮(HDN)、加氢脱硫(HDS)和加氢降烯烃(HYD)性能,反应温度为340℃和370℃,反应压力为3.0MPa。结果表明,在同样的制备条件下,MoP在各载体表面的分散情况明显不同。通过对4种负载型磷钼酸盐前体的程序升温还原过程(TPR)进行分析,发现以γAl2O3为载体的MoP催化剂,其DTG曲线在温度>400℃后只出现单峰;而其它载体负载的MoP催化剂其DTG曲线在温度>400℃后则出现多峰。在340℃时,以γAl2O3为载体的MoP催化剂的HDN、HDS和HYD效果最优。在370℃时,以TiO2为载体的MoP催化剂的HDN、HDS和HYD效果最优。

A bifunctional POM-based Cu-viologen complex with mixed octamolybdate clusters for rapid oxidation desulfurization and effective photogeneration of hydrogen

The design and synthesis of catalysts for the oxidation desulfurization and production of hydrogen are extremely important for solving environmental pollution and energy shortage.Herein,a novel bifunctional [α-Mo_(8)O_(26)]^(4-)/[β-Mo_(8)O_(26)]^(4-)-based Cu-viologen complex H_(4)[Cu_(2)~ⅠCl_(2)(Hbcbpy)_(4)] [α-Mo_(8)O_(26)] [β-Mo8O_(26)]·H_(2)O(BHU-2,Hbcbpy=1-(4-carboxybenzyl)-4,4'-bipyridinium) was synthesized and characterized by single-crystal X-ray diffraction(XRD),infrared radiation spectra,powder X-ray diffraction(PXRD) and X-ray photoelectron spectroscopy(XPS) spectra.The structural characteristic of BHU-2 is the presence of two types of octamolybdate clusters [α-Mo_(8)O_(26)]^(4-)/[β-Mo_(8)O_(26)]^(4-)and a new binuclear Cu~Ⅰ-Hbcbpy complex linked by Cl-bridges[Cu_(2)ⅠCl_(2)(Hbcbpy)_(4)]^(4+).BHU-2 as a heterogeneous catalyst exhibits excellent activities to the oxidation desulfurization and photocatalytic hydrogen production.At room temperature,BHU-2 can catalyze 96% conversion of methyl phenyl sulfide with 98% selectivity,and the process obeys the pseudo-first-order reaction kinetic with the half-life of9.6 min.The notorious 2-chloroethyl ethyl sulfide can achieve 99% conversion with 98% selectivity within only1 min at the presence of BHU-2,and the turnover frequency(TOF) is up to 7400 h^(-1).BHU-2 also exhibits high catalytic activity for the oxidation of other aromatic and aliphatic thioethers within short time at room temperature.Furthermore,BHU-2 shows a high catalytic activity for visible-light-driven hydrogen evolution with an H_(2) evolution rate of 1677.85 μmol·g^(-1)·h^(-1) within 10 h.Moreover,the catalytic activities do not decrease evidently after three cycles,revealing the prominent structural stability and recyclability.

含硫化氢油井高效治理技术研究及应用

针对三嗪脱硫剂在含硫化氢油井治理过程中存在硫容低、耐温性能差、易结垢等问题,研发了新型高效脱硫剂-DS脱硫剂体系。与三嗪脱硫剂相比,具有硫容高、耐温性好、不结垢等优势,同时可降低硫化氢治理成本约30%。为保证脱硫剂的应用效果,针对不同油井工况研发了套管滴加、井底注入等4种硫化氢治理工艺,其中研制的高含硫化氢油井井口催化氧化脱硫装置的脱硫率达95%以上。截至目前,硫化氢高效治理技术已应用超800井次,井口硫化氢含量可降至20 mg/m^(3)以下,为油田安全绿色生产提供了有力保障。

柴油加氢改质装置长周期运行影响因素分析

针对某企业原料性质劣质化,分析了原料柴油的密度、馏程95%温度点及硫含量升高对催化剂的影响,以及脱硫塔塔盘堵塞、反应流出物蒸汽发生器铵盐结晶问题等影响装置长周期运行的因素,提出优化原料性质、改善胺液质量和探索使用新型抗堵塞塔盘及在线水洗解决铵盐结晶等方案,以实现装置长周期运行。

渣油加氢装置催化剂全蜡油硫化技术应用总结

分析了固定床渣油加氢装置开工全部使用蜡油硫化方案的可行性。某公司首次采用全蜡油硫化对新鲜催化剂进行预硫化,全蜡油硫化可节省装置开工时间16 h,减少装置开工柴油使用量,减少产生不合格蜡油720 t,在低温硫化阶段蜡油硫化的上硫率更高,硫化更均匀。对比分析了全蜡油硫化与分阶段硫化的催化剂性能,在工艺条件、原料性质基本相同的条件下,两种不同方式硫化后的催化剂杂质脱除率同样高,活性相当。使用全蜡油硫化的催化剂运行周期相对较长,说明全蜡油硫化催化剂的稳定性较高。全蜡油硫化具有操作简单、节约资源、还原活性好等优点,对于其他同类装置具有借鉴意义,为今后同类装置开工优化预硫化操作提供了宝贵经验。

CuCl_(2)协同FeCl_(3)尿素低共熔溶剂氧化吸收H_(2)S的研究

为了解决中小规模常规含硫天然气H_(2)S脱除问题,以尿素(UREA)和FeCl_(3)·6H_(2)O为原料合成了一种FeCl_(3) UREA低共熔溶剂(DES),并向其中加入CuCl_(2)得到FeCl_(3) UREA-CuCl_(2)脱硫剂。分别对该DES的结构和热稳定性进行了测定,通过脱硫试验考察了原料配比、CuCl_(2)浓度、H 2S气体流量及温度对脱硫性能的影响,并对其再生过程进行了探究。结果表明:该DES在80℃下可稳定存在,FeCl_(3) UREA摩尔比1∶1的DES具有更为优异的脱硫性能;CuCl_(2)的引入可使其脱硫性能得到大幅提升,最高硫容达9.64 g L。该脱硫剂更适用于较低气体流速时脱硫使用,且可通入O_(2)进行再生,脱硫剂经多次循环使用后性能变化不大。脱硫所得产物为高纯度斜方硫(α-硫)。该脱硫剂原料成本低廉,合成简单,可高效氧化吸收H_(2)S并将其转化为高纯度硫磺,为工业天然气脱硫提供参考。

共沉淀法制备常温锌基脱硫剂的研究

在我国聚丙烯产业快速发展的背景下,硫作为丙烯聚合反应中的有害杂质,对聚丙烯产品的质量及装置的正常运行产生不利影响,因此如何有效去除原料丙烯中硫等有害杂质成为一个关键问题。本研究采用共沉淀法,选用六水合硝酸锌[Zn(NO_(3))2·6H_(2)O]和六水合氯化铝(AlCl_(3)·6H_(2)O)分别作为活性组分和载体成分,以碳酸钠(Na_(2)CO_(3))为沉淀剂,制备一种高效的常温锌基脱硫剂。经过单因素试验,确定了最优条件:陈化温度60℃、锌盐和铝盐摩尔比4∶1、锌盐和铝盐与沉淀剂摩尔比1∶1.3、锌盐浓度0.75 mol L、焙烧温度300℃,制得的脱硫剂穿透硫容达到22.69%。进一步分析表明,脱硫剂前躯体为碱式碳酸锌,最佳焙烧温度300℃,此时脱硫活性最高(穿透硫容22.69%),且孔结构性质优异(比表面积67.63 m^(2)/g,孔体积0.202 cm^(3)/g,平均孔径10.94 nm)。在25℃下的性能评价结果表明,所制备锌基脱硫剂表现出卓越的脱硫性能,穿透时间长达600 min,穿透硫容为23.17%。

多酸基UiO-66的合成及其对硫化氢的脱除性能

硫化氢具有较强的毒性和腐蚀性,高效脱除硫化氢对于工业生产、环境治理等过程意义重大。该文基于钼基杂多酸(HPAs),以UiO-66为载体,一步水热合成HPAs@UiO-66,构建不同活性中心多酸基固相脱硫体系,考察杂多酸结构(Keggin、Dawson)、中心原子(P、Si)、取代原子(V、W)对脱硫的影响,并通过BET、FT-IR、XRD、SEM、TEM进行理化性质分析。结果表明,PMo_(12)@UiO-66脱硫活性最高,且其脱硫能力在100℃时最佳,吸附量可达到17.18 mg/g,同时发现水分对其脱硫具有促进作用。与PMo_(12)和UiO-66相比,PMo_(12)@UiO-66表现出明显脱硫优势,其吸附量分别为PMo_(12)和UiO-66的7.5和14.2倍,证明了PMo_(12)与UiO-66具有协同脱硫作用。XPS结果表明,PMo_(12)与H_(2)S之间发生了氧化还原反应,H_(2)S在PMo_(12)氧化作用下被转化成单质硫。研究表明PMo_(12)的引入对UiO-66脱硫性能的强化作用最为显著,可为开发新型多酸基固相脱硫剂提供参考。

天然气最终脱硫槽筒体开裂及封头鼓包原因分析

天然气最终脱硫槽在服役时筒体部位发生开裂并引发起火事故,利用化学分析、金相检验、力学性能测试及断口形貌分析等手段对筒体开裂和封头鼓包的原因进行了分析。分析结果表明:在设备服役过程中,筒体和封头内部发生了氢腐蚀现象,进而使得材料内部产生了孔洞,导致材料强度下降,冲击韧性变差,最终在筒体外表面萌生裂纹造成筒体开裂;封头处产生的孔洞数量少于筒体开裂处,且本身壁厚大于筒体,在筒体开裂后内部压力减小,造成封头鼓包。

干法脱硫工艺在煤层气田的应用——以沁水盆地潘河区块为例

本文以沁水盆地潘河区块15号煤产出气中硫化氢的脱除工艺为例,结合煤层气田的集输工艺和生产情况,阐述了如何进行脱硫工艺选择、脱硫药剂选择、安装位置选择、工艺设计,并对煤层气区块的伴生硫化氢处理提出合理建议。

钢铁行业高炉煤气精脱硫技术应用现状和未来趋势研究

高炉炼铁处于长流程钢铁冶炼生产工艺中的关键环节,高炉煤气是炼铁过程副产的重要二次能源,通常在高炉热风炉、轧钢加热炉和自备电厂煤气发电等生产工序进行燃烧利用。高炉煤气精脱硫技术的工程应用作为钢铁行业进行源头减排的典型实施方案具有非常重要的意义,国家与地方相关部门对于高炉煤气脱硫技术的应用也明确提出了最新要求。结合高炉煤气组分复杂、工况波动的特征和硫组分形态不同、有机硫为主的含硫特点以及不同脱硫技术的主要特点,重点分析了针对煤气中硫化氢的脱除方法、羰基硫的脱除方法以及硫化氢和羰基硫的一体化脱除方法,并通过对近年来钢铁行业高炉煤气精脱硫技术的工程应用现状调研,进一步对高炉煤气精脱硫技术后续的研发方向和工程应用等方面提出了几点建议。

催化柴油低压深度加氢脱硫可行性研究

为解决某炼化企业劣质催化柴油大量过剩的问题,计划对装置进行改造,适当降低装置加工量,以满足加工催化柴油的需求。为确认方案的可行性,在加氢中试装置进行了可行性试验。结果表明,对低压加氢装置进行改造后,可以满足处理催化柴油的要求;在反应压力4.0 MPa、平均反应温度350℃、体积空速0.55 h^(-1)、氢油体积比300的条件下,精制柴油硫含量可以满足国Ⅵ标准柴油调和组分的要求。

GLT络合铁脱硫工艺在加氢精制含硫尾气净化中的应用

GLT络合铁脱硫工艺可将中小规模加氢精制装置产生的各种含H2S尾气净化至ρ(H_(2)S)<5mg/m^(3),净化后尾气可再进行资源化利用,脱除的硫用于生产工业硫黄。与传统的MDEA富集后回收硫的工艺相比,GLT络合铁脱硫工艺流程简单,节能环保,无“三废”排放,具有良好的经济效益与环保效益。