Experimental Study of Integrated Ebullated-bed and Fixed-bed for Hydrotreating Mid-Low Temperature Coal Tar to Clean Fuel

A new hydrotreating technology integrating the ebullated-bed(EB) and the fixed-bed(FB) hydrogenation was proposed to investigate the efficiency for hydrotreating mid- low-temperature coal tar to clean fuel, and multiple tests at the bench scale were carried out. The results showed that the distillates obtained from EB reactors were greatly upgraded and could meet the requirements of FB unit without discarding any tail oil. The naphtha produced from FB reactors could be fed to the catalytic reforming unit, while a high quality diesel was also obtained. The unconverted oil(UCO) could be further hydrocracked to clean fuel. It is found that the removal of impurities from the coal tar oil is related with the molecular aggregation structure and composition of the coal tar. Application of the integrated hydrotreating technology to the hightemperature coal tar processing demonstrated that more than half of heavy components could be effectively upgraded.

Investigation of the liquid recycle in the reactor cascade of an industrial scale ebullated bed hydrocracking unit

One of the commercial means to convert heavy oil residue is hydrocracking in an ebullated bed. The ebullated bed reactor includes a complex gas–liquid–solid backmixed system which attracts the attention of many scientists and research groups. This work is aimed at the calculation of the internal recycle flow rate and understanding its effect on other parameters of the ebullated bed. Measured data were collected from an industrial scale residual hydrocracking unit consisting of a cascade of three ebullated bed reactors. A simplified block model of the ebullated bed reactors was created in Aspen Plus and fed with measured data. For reaction yield calculation, a lumped kinetic model was used. The model was verified by comparing experimental and calculated distillation curves as well as the calculated and measured reactor inlet temperature. Influence of the feed rate on the recycle ratio(recycle to feed flow rate) was estimated. A relation between the recycle flow rate, pump pressure difference and catalyst inventory has been identified. The recycle ratio also affects the temperature gradient along the reactor cascade. Influence of the recycle ratio on the temperature gradient decreased with the cascade member order.

Reaction Process of Heavy Hydrocarbons Hydrogenation in Ebullated Bed

The properties and structural changes of unconverted oil(UCO)obtained from ebullated bed hydrogenation at different residue conversion rates were analyzed to clarify the reaction process of heavy components.Meanwhile,the processing routes of UCO,delayed coking,and solvent deasphalting,were investigated.The results showed that with the increase of conversion,the impurity removal rate increased;meanwhile the contents of sulfur and metal in UCO decreased,while the contents of nitrogen and residual carbon increased,and the colloidal stability of UCO became worse.The structural parameters of UCO indicated that the change in molecular structure of heavy oil mainly covered the opening of cycloalkanes ring,hydrogenation saturation of aromatic rings and dealkylation reaction during hydrogenation in the ebullated bed;the aromatic structure was basically unchanged at high conversion,and was mainly due to the ring opening of cycloalkanes and the fracture reaction of alkyl side chains.The coking route of UCO showed that low sulfur petroleum coke with different grades could be prepared by adjusting the conversion in ebullated bed to produce UCOs with different properties.The coke generating coefficient and sulfur transfer coefficient in UCO coking process were higher than those in residue coking.The properties of deasphalted oil(DAO)of UCO were significantly improved and could be used as FCC or hydrocracking feedstock.The DAO yield of UCO feedstock at high conversion was higher,and its sulfur content was lower and CCR value was higher.

LDRA TestBed在CTCS2-200C扩展单元软件测试中的应用

介绍了LDRA Test Bed软件测试工具和CTCS2-200C扩展单元,以CTCS2-200C为例,通过对软件进行静态和动态测试,参照EN 50128:2011标准,提高了整个软件开发生命周期中的各项验证和确认活动效率,降低了软件的风险。

比较BED-CEIA法和LAg-Avidity EIA两种方法检测HIV-1新发感染的应用价值

目的探讨BED捕获酶联法(BED-CEIA)和限制性抗原亲和力酶联免疫方法(LAg-Avidity EIA)检测艾滋病病毒-1(HIV-1)新发感染的应用价值。方法选取2019年1月至10月在我院治疗的HIV-1新发感染者130例,抗病毒治疗者100例,均给予BED-CEIA和LAg-Avidity EIA方法检测。结果BED-CEIA和LAg-Avidity EIA判断新发感染正确率分别为77.69%和84.62%,差异比较无统计学意义(P>0.05);不同性别、年龄患者BED-CEIA和LAg-Avidity EIA判断新发感染正确率比较差异无统计学意义(P>0.05);ED-CEIA和LAg-Avidity EIA检查ODn值呈正相关(r=0.420,P<0.05);在抗病毒治疗者中,BED-CEIA和LAg-Avidity EIA误判新发感染率分别为17.00%和13.00%,比较差异无统计学意义(P>0.05)。结论BED-CEIA法和LAg-Avidity EIA两种方法检测HIV-1新发感染均有较好的价值。

适应炼油厂转型发展的沸-固复合床渣油加氢技术开发

为适应炼油厂转型发展需求,依托S-RHT固定床渣油加氢技术和STRONG沸腾床渣油加氢技术,中石化(大连)石油化工研究院有限公司开发了沸-固复合床渣油加氢技术。该技术采用单台沸腾床反应器承担原料预处理功能,大大改善了固定床进料性质,多台固定床反应器承担深度加氢精制功能,可明显提升加氢产品质量。中试试验结果表明:经过沸腾床反应器加工,劣质渣油原料金属(镍+钒)质量分数由123.1μg/g降低至38.9μg/g,后经过固定床反应器加工,金属质量分数降至8.8μg/g,加氢脱金属率达92.85%;该原料经过沸-固复合床加氢处理后氢质量分数增加1.58百分点,加氢脱硫率达到90.69%,加氢脱残炭率达到70.30%,加氢脱氮率达到53.73%,沥青质转化率达到82.87%。沸-固复合床渣油加氢技术实现了重质渣油的深度加氢转化,充分发挥了沸腾床和固定床加氢工艺各自的优势,可为后续加工装置提供优质进料。

Treatment of Dyes Wastewater by a New Kind of Bio - Fluid Bed

A new kind of bio-fluid bed used to treat dyes wastewater is described in detail due to its several special features,such as high removal efficiency,simple struc-ture,shock load resistance,etc.By means of analyzing the experiment data,the results show that the dye wastewater’s organic matter is removed greatly after be-ing treated by this new kind of bio-fluid bed.On the other hand,the removal efficiency of chromaticity of

沸腾床渣油加氢-焦化组合工艺探讨

针对劣质渣油加工,分别采用沸腾床渣油加氢-焦化组合工艺与单独焦化工艺两种技术路线进行探讨,以选择其适合的加工技术路线。结果表明,劣质渣油原料经沸腾床加氢,产品杂质含量显著降低。在双反应器温度基准+5/基准+5、基准空速条件下,劣质渣油加氢产品的S、Ni、V质量分数分别下降了90%、95%、99%。与劣质渣油原料相比,沸腾床加氢减压渣油的性质得到极大改善。与单独焦化工艺相比,采用组合工艺加工劣质渣油,总液体产率提高了13.57%,增产高附加值产品的能力明显提升,从而大幅度提高经济效益。同时,该组合工艺具有改善油品稳定性、原料适应性广、工艺灵活等明显优势,是提高原油资源利用率的较佳方案。

催化剂形貌对沸腾床渣油加氢Ni-Mo/Al_(2)O_(3)催化剂活性位的影响机制

随着原油供应趋于劣质化和严格的环保法规出台,沸腾床渣油加氢技术引起了广泛关注。采用挤压成型法和STRONG沸腾床的特殊成型法分别制备了圆柱形和球形Ni-Mo/Al_(2)O_(3)催化剂,系统地研究了催化剂的颗粒形貌对活性相和渣油加氢性能的影响。采用XRD、N_(2)物理吸脱附、H_(2)-TPR、HRTEM、XPS和电子微探针分析等手段对催化剂进行了表征。结果表明,球形催化剂具有活性更强的TypeⅡ类型活性位点、更优异的孔道结构性质和更好的流化性能,这使得其具有更高的渣油加氢活性。球形催化剂中的金属和载体之间相互作用较弱,这有利于形成更高硫化程度和堆垛层数的Ni-Mo-SⅡ型活性相,这种活性相在渣油加氢中具有更高的活性。此外,球形催化剂具有比圆柱形催化剂更大的孔径和孔体积,这有利于大分子杂质在孔道中的扩散和活性位点上的吸附,并且使得金属沉积物均匀分布在球形催化剂中,而不是集中分布在孔口。而且球形催化剂尺寸更小,可能更易于流化,这增强了催化剂的传质性能。

沸腾床-固定床组合渣油加氢处理技术研究

沸腾床渣油加氢技术与固定床渣油加氢技术组合可以明显改善固定床进料性质,大幅度降低杂质含量,大大改善固定床操作;同时可以扩大可加工的原料范围,延长操作周期。中试数据表明,加工金属质量分数分别为118,233μg/g、残炭质量分数分别为15.7%,21.1%的劣质渣油,沸腾床与固定床组合工艺均可稳定操作,所得加氢渣油金属质量分数分别为10.6,7.8μg/g,残炭质量分数分别为5.6%,5.2%,可以直接作为催化裂化装置原料,从而实现劣质渣油的高效转化。通过技术特点和技术经济分析,并与单独的固定床方案对比,发现沸腾床与固定床组合渣油加氢处理新技术具有更好的盈利能力,并可实现3 a稳定运转,从而与下游装置相匹配,实现同步开停工。

沸腾床加氢FFT-1B催化剂的首次国产化工业应用及性能评价

介绍了中国神华煤制油化工有限公司鄂尔多斯煤制油分公司与中国石化抚顺石油化工研究院合作开发的T-Star沸腾床FFT-1B催化剂的工业应用情况,通过对反应温升、氢耗、供氢溶剂的供氢性以及催化剂性能等参数进行分析,对FFT-1B催化剂性能进行评价。工业应用结果表明,FFT-1B催化剂的性能稳定,反应温升大、氢耗高、供氢溶剂的供氢性能得到显著改善,沸腾床催化剂国产化应用成功。

T-STAR工艺的发展及其在煤液化工艺中的应用

对T-STAR工艺的产生、工艺特点及其发展应用进行综述,重点介绍该工艺在神华煤制油化工有限公司鄂尔多斯煤制油分公司煤直接液化项目上的首次应用情况及其工艺过程。通过对反应原料、产品和反应器内温度分布等方面的考察,阐述T-STAR装置与煤直接液化装置配套应用的优点,展望T-STAR工艺的应用前景。

沸腾床加氢-焦化组合工艺制备低硫石油焦

对沸腾床加氢-焦化组合工艺制备高品质石油焦的工艺路线进行研究,探究沸腾床未转化油(UCO)的焦化规律。结果表明:渣油沸腾床加氢反应过程中,提高温度或降低空速有利于渣油转化率和杂质脱除率提高;同样的操作区间内,渣油转化率的变化明显大于杂质脱除率;随着渣油转化率增加,UCO硫含量先降低再升高。UCO焦化过程中原料中60%左右的硫转移到焦炭中,明显高于渣油焦化过程中硫转移到焦炭的比例(约42%);相比于渣油直接焦化得到的焦炭,较低硫含量的UCO制备的石油焦品质明显提升。UCO焦化所得石油焦收率和硫含量分别与UCO的残炭和硫含量呈现良好的线性关系,可根据所需低硫焦牌号来指导沸腾床加氢过程的工艺优化。

用于转化劣质渣油的LC-FiningSM沸腾床渣油加氢工艺

LC-FiningSM沸腾床渣油加氢工艺是一种高效而且可靠的劣质渣油加氢工艺。该工艺既可以在低转化率下生产低硫优质燃料油或合成原油,也可以在高转化率下将劣质渣油转化为馏分油为下游装置提供优质原料或者在流程内增加固定床加氢精制反应器的模式下直接生产清洁燃油。

具阶段结构和Bedding DeAngelis功能反应的食饵捕食系统(英文)

研究具阶段结构和Bedding-DeAngelis功能反应的食饵捕食系统.给出了一致持续生存和捕食者灭绝的条件.

沸腾床渣油加氢裂化装置投产对重油制氢装置的影响

沸腾床渣油加氢裂化装置投产后,将溶剂脱沥青装置的原料由常减压装置洗涤油和减压渣油调整为渣油加氢裂化装置未转化油,作为重油制氢装置原料的脱油沥青性质由此发生变化。对比重油制氢装置原料油性质、主要操作参数、技术经济指标、气化炉运行周期等参数,结果表明,渣油加氢裂化装置投产后,以脱油沥青为原料的重油制氢装置气化炉油气分布更均匀,气化单元有效气含量提高2.12个百分点,有效气产率提高0.20个百分点,碳转化率提高0.18个百分点,氢气产率提高1.21个百分点,吨氢标油能耗下降140 kg,装置各项技术经济指标均有较大幅度提升,气化炉烧嘴运行周期明显延长。

沸腾床渣油加氢裂化装置结焦情况分析与操作优化

分析了沸腾床渣油加氢裂化装置易结焦堵塞的原因,介绍了某炼化公司沸腾床渣油加氢裂化装置易结焦区域和结焦典型症状,从原料、催化剂、反应和分馏工况等方面进行了优化。通过将原料渣油引入脱固油浆减缓结焦,动态调整渣油转化率控制装置结焦:加工中东高硫低氮原油所产渣油时,转化率可控制在75%以上;加工低硫中东原油所产渣油时,转化率控制在不大于70%;加工低硫高氮原油所产渣油时,转化率控制在不大于65%。每吨渣油原料置换新鲜催化剂0.90~0.95 kg,低控减压塔塔底液位(25%~30%),提高塔底物料返混流量以减少沥青质在塔底器壁生焦。优化操作后,常压塔底油总沉积物质量分数稳定小于0.2%,确保了装置在渣油高转化率下的长周期稳定运行。

沸腾床渣油加氢裂化装置紧急泄压限流孔板核算

在事故处理中,高压加氢装置的紧急泄压速率对于安全生产至关重要。装置的紧急泄压速率与紧急泄压系统限流孔板孔径等参数相关。文中介绍了一种沸腾床渣油加氢裂化装置紧急泄压系统限流孔板孔径的校对计算方法。通过理论计算验证装置的泄压速率是否满足设计要求,进一步计算实际需要的孔板孔径,从而大大减少了试验次数,缩短开工试车时间。以某炼油厂沸腾床渣油加氢裂化装置为研究对象,装置在试车阶段,高压氢气工况下启动联锁条件,手动打开紧急泄压阀按钮进行紧急泄压试验。根据计算公式校核孔板孔径,把试验孔板孔径由34.5 mm改为41.0 mm,经过试验验证满足实际生产要求。

沸腾床加氢装置用球阀的优化设计及应用

影响沸腾床加氢装置球阀长期安全有效运行的原因主要有开关动作卡涩、开关不到位、球体与阀座流道口被冲蚀等,结合现役球阀的应用工况,通过流体仿真分析以及密封面耐磨冲蚀综合试验,运用理论分析和有限元软件,实现球阀的优化设计,同时对阀门的应用情况进行了解析,给出了球阀安装调试的注意事项,能更好地满足工况条件和使用要求。

沸腾床蜡油氮化物分析及加氢裂化工艺研究

以常规减压蜡油和沸腾床蜡油为原料,利用高分辨质谱对比了两种原料中氮化物的分子结构及变化规律,在常规减压蜡油中掺炼不同比例的沸腾床蜡油为混合油,并以此为原料进行加氢裂化反应,考察了工艺条件对产物分布及产品性质的影响。实验结果表明,与常规减压蜡油相比,沸腾床蜡油的密度更大,馏程范围较窄,具有更多的大分子烃类物质,组分中的氮化物主要为五环非碱性氮化物,在加氢裂化工艺中脱除难度大。在相同的加氢裂化催化剂体系下,加工混兑沸腾床蜡油的混合油与单独加工常规减压蜡油在产物分布上没有太大变化,产品性质根据混兑比例不同存在差异。