CO_2加氢合成二甲醚的适宜工艺条件

采用甲醇合成催化剂C207和分子筛HZSM-5混合制得CO2加氢合成二甲醚双功能催化剂,并在微型固定床反应装置上进行了活性评价。考察了反应温度、压力、氢碳摩尔比、空速等工艺条件对催化反应的影响。结果表明,温度对催化剂活性影响显著,适当提高温度有利于提高反应速率,适宜的温度操作范围260～270℃,增加压力,提高氢碳摩尔比有利于提高CO2转化率、二甲醚收率;适宜的空速范围1500～3000h-1。     

浆态床合成气制二甲醚反应器数学模拟

建立了包括液相返混和催化剂颗粒沉降的合成气一步法制二甲醚浆态床反应器的数学模型,模拟计算了空速、原料气组成、反应温度、反应压力等反应条件对反应的影响。计算结果表明,CO转化率和二甲醚的选择性随温度增加、压力增大而提高,在一定温度、压力条件下,CO转化率随空速增大而减小,合成气含有一定量的CO2有利于CO转化率增加。     

三相床中合成气一步法制二甲醚的研究

在反应压力3－5MPa、温度230－270℃,以医药用石蜡油为惰性液相介质,C302铜基催化剂和CM－3－1改性分子筛组成的复合催化剂,在不同催化剂配比,研究了在三相搅拌釜中合成气（CO、CO2、H2）一步法合成二甲醚的反应。结果表明随着温度升高,碳的转化率增加、二甲醚的选择性增加、甲醇的选择性降低;随着压力的增加,碳的转化率升高,二甲醚的选择性增加、甲醇的选择性降低;合成二甲醚催化剂CM－3－1比例提高时,反应转化率降低,二甲醚的选择性提高。     

合成气一步法制二甲醚工艺条件研究

研究了三相床反应器中合成气一步法制二甲醚的工艺条件,催化剂是由甲醇合成催化剂与甲醇脱水催化剂均匀混合组成的双功能催化剂.在温度220～265℃、压力4～5MPa、空速1～2 L/(g·h)的条件下,分别考察了温度、压力和空速对二甲醚合成反应中CO转化率及二甲醚选择性的影响.结果表明,在上述各因素相应的范围内,,随着反应温度的升高,CO转化率、DME选择性逐渐增加;随着压力的升高,CO转化率、DME选择性逐渐增加;CO转化率、DME选择性随空速的提高而逐渐减小.与固定床实验结果相比,三相床反应器中CO转化率略低于固定床反应器.     

三相床中合成气一步法制二甲醚

在反应温度 2 30～ 2 70℃、压力 2～ 5MPa下 ,以医药用石蜡油为惰性液相介质 ,使用C30 2铜基催化剂和CM - 3- 1改性分子筛组成的复合催化剂 ,在三相搅拌釜中研究了合成气 (CO、CO2 、H2 )一步法合成二甲醚的反应。结果表明随着温度的升高 ,碳的转化率增加 ,二甲醚的选择性提高 ,甲醇的选择性降低 ;随着压力的增加 ,碳的转化率升高 ,二甲醚的选择性提高 ,甲醇的选择性降低     

浆态床中二氧化碳加氢合成甲醇

研究了浆态床中自行开发的LP201甲醇合成催化剂上二氧化碳加氢合成甲醇的过程。探讨了不同操作条件,如温度、压力、气体空速、原料气配比等对反应的影响;考察了该催化剂在浆态床二氧化碳加氢合成甲醇过程中的稳定性。实验结果表明,浆态床二氧化碳加氢合成甲醇过程中主要产物为甲醇、CO和水;随温度的增加,CO2的转化率和甲醇产率呈现上升的趋势,但甲醇的选择性明显下降;压力的升高有利于CO2的转化率、甲醇产率以及甲醇的选择性提高;原料气空速的提高会增大甲醇产率,但同时降低CO2的转化率以及甲醇的选择性;CO2的转化率、甲醇收率以及甲醇的选择性在氢碳摩尔比4～5获得极大值。LP201催化剂的寿命考察结果表明,该催化剂具有较好的催化活性和稳定性。     

生物质合成气合成二甲醚的研究

在加压固定床反应装置上进行了生物质合成气合成二甲醚(DME)的研究.采用机械混合法制备二甲醚合成双功能催化剂.考察了组成为V(H_2):V(CO):V(CO_2):V(CH_4)=52:24:23:1的生物质合成气在不同反应温度、空速、压力下对合成二甲醚反应的影响.同时进行了102 h的催化剂的稳定性实验.结果表明,在260-300℃范围内,随反应温度的升高,CO转化率和二甲醚的选择性均先增大后减小;随反应压力的升高,CO转化率和二甲醚选择性都随之升高;原料气中高浓度的CO_2可导致铜基催化剂较快的失活.     

三相搅拌反应釜中合成气直接制二甲醚

在三相搅拌反应釜中,以医用石蜡油为惰性液相介质,以铜基催化剂与改性分子筛组成固相复合催化剂,以合成气为原料气,研究了CO、CO2、H2一步法合成二甲醚（DME）的催化反应,考察了温度、压力、原料气组成对反应结果的影响。研究结果表明,反应温度提高或反应压力提高,CO与CO2的总转化率增加,二甲醚的选择性增加;含有一定比例CO2的原料气,碳总转化率较大,二甲醚选择性较高。     

CO2加氢合成乙醇热力学分析及催化研究进展

综述了CO2的分子结构及性质、CO2加氢合成乙醇催化剂的催化性能和该反应的反应机理;还对CO2加氢合成乙醇反应进行了热力学分析,计算出不同反应条件下系统的平衡组成和CO2平衡转化率,并讨论了反应温度、压力及进料比对CO2平衡转化率的影响。结果表明,CO2平衡转化率随温度的升高而下降,增大反应体系的压力和采用高的氢碳比,对提高CO2平衡转化率有利。     

浆态床中合成二甲醚的研究

考察了浆态床中3种甲醇合成催化剂反应行为,考察了温度、压力、催化剂比例和种类对二甲醚合成的影响.结果表明,低压下甲醇合成催化剂中C30l活性最好,温度降低和压力升高有利于甲醇的合成.二甲醚合成中,不同脱水催化剂反应性能不同.在考察范围内,温度升高,CO转化率变化不大,二甲醚的选择性增加;压力升高,CO转化率和二甲醚选择性都随之升高;两种催化剂(C301Hβ)的质量比为41时,CO转化率和二甲醚选择性最高.     

CO_2加氢合成甲酸适宜工艺条件的研究

采用浸渍-化学还原法制备负载型Cu基催化剂,在微型反应装置上进行了活性评价,考察了反应温度、压力、氢碳摩尔比、空速等工艺条件对催化反应的影响。结果表明,温度和压力对催化剂活性影响显著,升高温度,增加压力有利于提高CO2转化率、甲酸收率,适宜的氢碳摩尔比为4左右,空速范围5 000～11 000 h-1。     

CO2加氢合成甲酸适宜工艺条件的研究

采用浸渍-化学还原法制备负载型Cu基催化剂,在微型反应装置上进行了活性评价,考察了反应温度、压力、氢碳摩尔比、空速等工艺条件对催化反应的影响。结果表明,温度和压力对催化剂活性影响显著,升高温度,增加压力有利于提高CO2转化率、甲酸收率,适宜的氢碳摩尔比为4左右,空速范围5 000～11 000 h-1。     

完全液相法制CuZnAl合成二甲醚浆状催化剂的催化性能

利用完全液相法制备了CuZnAl浆状催化剂,考察了反应温度、反应压力、搅拌速度、原料气组成等工艺条件, 以及催化剂中各组分配比对浆态床合成气一步法合成二甲醚反应过程的影响。结果表明, 利用完全液相法制备的催化剂在升温段和降温段活性保持稳定,随着反应时间的延长,催化剂活性呈现增长趋势,且其水煤气变换反应速率很快。Cu/Zn/Al摩尔比为1∶1∶2.09时催化剂的CO转化率与DME 选择性最好。     

Experimental study of improved two step synthesis for DME production

Dimethyl ether (DME) has received growing attention due to its potential use as a multi-purpose fuel. A new technical route of improved two step synthesis is proposed for DME production, which is composed of methanol synthesis and methanol dehydration in a fixed-bed reactor. The influences of the operating conditions including reaction pressure, temperature, H₂/CO mole ratio in the syngas and space velocity on CO conversion, selectivity and yield of DME are investigated. CO conversion and DME yield both increase monotonically with the pressure increase. The optimal reaction temperatures for the synthesis and dehydration of methanol are different. CO conversion increases at first and keeps constant when the H₂/CO mole ratio is above 2. DME yield increases obviously and then decreases gradually with the space velocity increase. The optimal conditions are obtained to maximize the CO conversion and DME selectivity. The reaction temperatures of the top and bottom stage are in the range of 270-280 °C and 235-245 °C, respectively. The optimal ratio of H₂/CO is above 2, and the space velocity is in the range of 1000-1300 h^− 1.     

能源化工与催化固定床一步法制二甲醚催化剂性能

采用固定床反应装置,以共沉淀法制备甲醇催化剂和一步法合成二甲醚催化剂,采用BET、XRD和SEM对催化剂进行表征。在反应压力2.5 MPa、反应温度260 ℃和空速(500~900) h^-1条件下,催化剂催化活性最好,其中,CO转化率≥90%,二甲醚收率≥60%,二甲醚选择性≥65%。     

Enhanced stability of Fe-modified CuO-ZnO-ZrO2-Al2O3/HZSM-5 bifunctional catalysts for dimethyl ether synthesis from CO2 hydrogenation

A series of iron (Fe) modified CuO-ZnO-ZrO2-Al2O3 (CZZA) catalysts,with various Fe loadings,were pre-pared using a co-precipitation method.A bifunctional catalyst,consisting of Fe-modified CZZA and HZSM-5,was studied for dimethyl ether (DME) synthesis via CO2 hydrogenation.The effects of Fe loading,reaction temperature,reaction pressure,space velocity,and concentrations of precursor for the synthesis of the Fe-modified CZZA catalyst on the catalytic activity of DME synthesis were investigated.Long-term stability tests showed that Fe modification of the CZZA catalyst improved the catalyst stability for DME synthesis via CO2 hydrogenation.The activity loss,in terms of DME yield,was significantly reduced from 4.2％ to 1.4％ in a 100 h run of reaction,when the Fe loading amount was 0.5 (molar ratio of Fe to Cu).An analysis of hydrogen temperature programmed reduction revealed that the introduction of Fe improved the reducibility of the catalysts,due to assisted adsorption of H2 on iron oxide.The good stability of Fe-modified CZZA catalysts in the DME formation was most likely attributed to oxygen spillover that was introduced by the addition of iron oxide.This could have inhibited the oxidation of the Cu surface and enhanced the thermal stability of copper during long-term reactions.     

Pd-Ag/α-Al2O3催化剂在乙烷裂解配套制乙烯工艺中的选择加氢性能研究

在乙烷裂解配套制乙烯选择加氢的工艺条件下,考察载体焙烧温度、助剂Ag含量、溶液pH值、CO含量及空速对等体积浸渍法制备的Pd-Ag/α-Al₂O₃催化剂性能的影响。结果表明,载体焙烧温度的增加,有助于提高催化剂活性;催化剂Ag含量增加,反应温度变化不大,选择性及抗结焦性能增加;不同溶液pH制备催化剂,选择加氢性能差异不大,但溶液的酸性过高会降低催化剂的抗结焦性能;随着CO的升高,乙炔转化率降低,乙烯选择性先增高后降低,为保证催化剂选择性,原料中的CO最好保持在(700~1 600) μL·L^-1;随着空速的升高,乙炔转化率降低,乙烯选择性增加。     

二甲醚水蒸气重整制氢CuO-ZnO-Al2O3-ZrO2/固体酸复合催化剂

Steam reforming(SR) of dimethyl ether(DME) was investigated for the production of hydrogen for fuel cells.The activity of a series of solid acids for DME hydrolysis was investigated.The solid acid catalysts were ZSM-5 [Si/Al=25,38 and 50:denoted Z(Si/Al)] and acidic alumina(γ-Al₂O₃) with an acid strength order that was Z(25)>Z(38)>Z(50)>γ-Al₂O₃.Stronger acidity gave higher DME hydrolysis conversion.Physical mixtures containing a CuO-ZnO-Al₂O₃-ZrO₂ catalyst and solid acid catalyst to couple DME hydrolysis and methanol SR were used to examine the acidity effects on DME SR.DME SR activity strongly depended on the activity for DME hydrolysis.Z(25) was the best solid acid catalyst for DME SR and gave a DME conversion>90% [T=24℃,n(H₂O)/n(DME)=3.5,space velocity=1179 ml·(g cat)^-1·h^-1,and P=0.1MPa].The influences of the reaction temperature,space velocity and feed molar ratio were studied.Hydrogen production significantly depended on temperature and space velocity.A bifunctional catalyst of CuO-ZnO-Al₂O₃-ZrO₂ catalyst and ZSM-5 gave a high H₂ production rate and CO₂ selectivity.     

Effect of pressure on direct synthesis of DME from syngas over metal-pillared ilerites and metal/metal-pillared ilerites

The effect of pressure on the direct synthesis of dimethyl ether (DME) from syngas over metal (Cu, Zn) pillared ilerites and metal (Cu, Zn) impregnated metal-pillared ilerites was explored. The prepared catalysts were characterized by XRD, BET, ICP-AES, SEM and FT-IR. The direct DME synthesis reaction was carried out in a differential fixed bed reactor with the prepared catalysts at various pressures (10, 20, 30 bar), 250°C and H₂/CO ratio of 2. The Cu/Zn-pillared ilerite catalyst showed the highest catalytic activity among the prepared catalysts at 20 bar, in which CO conversion was about 62% and DME selectivity was about 89%. CO conversion increased with pressure, and DME selectivity increased with pressure in the range of 10–20 bar, and above the pressure slightly decreased with pressure. The optimum pressure for this reaction was 20 bar.     

钒基MSU-1催化剂上二氧化碳氧化异丁烷脱氢反应条件的优化研究

以介孔材料MSU-1为载体,不同金属氧化物为活性组分,分别制备负载型催化剂并研究其在CO<,2>气氛中异丁烷脱氢的催化活性.结果证明VOx/MSU-1催化剂有最好的异丁烷氧化脱氢催化活性.基于此,对影响CO<,2>氧化异丁烷脱氢的温度、空速和氧烷比等工艺条件进行了考察,结果显示,当温度为853 K,空速为7200 mL...