Simulation of biodiesel industrial production via solid base catalyst in a fixed-bed reactor

Biodiesel industrial production based on a solid base catalyst in a fixed-bed was simulated. The lab and bench scale experiments were carded out effectively, in which the kinetic model is established and it can describe the transesterification reaction well. The Antoine equation of biodiesel is regressed with the vapor-liquid data cited of literature. The non-random two liquid （NRTL） model is applied to describe the system of fatty acid methyl ester （FAME）, methanol and glycerol and parameters are obtained. The Ternary phase map is obtained from Aspen Plus via the liquid-liquid equilibrium （LLE） data. In order to describe the production in a fixed-bed performs in industrial scale after being magnified 1 000 times, the Aspen Plus simulation is employed, where two flowsheets are simulated to predict material and energy consumption. The simulation results prove that at least 350. 42 kW energy consumption can be reduced per hour to produce per ton biodiesel compared with data reported in previous references.

A Simulation Study of the Steam Reforming of Methaneina Fixed-Bed Reactor

In this work a one-dimensional mathematical model was developed to simulate methane conversion and hydrogen yield in a fixed-bed reactor filled with catalyst particles. For the reason that reforming reactions are sorely endothermic process, the heat is supplied to the reactor through electrical heating. The reforming reactions have been investigated from a modelling view point considering the effect of different temperatures ranging from 500℃ and 977℃ on the conversion of methane and hydrogen yield. Simulation results show that the steam reforming of methane in a fixed-bed reactor can efficiently store high temperature end thermal energy. When the operating temperature is increased to 977℃, the conversion of methane is 97.48% and the hydrogen yield is 2.2408. As a conclusion, the maximum thermochemical efficiency will be obtained under optimal operating temperature (977℃) and the steam/methane (3.86) ratio.

Research on process modeling and simulation of spent lead paste desulfurization enhanced reactor

In the reaction process of carbonate desulfurization lead paste,the produced PbCO_(3) is easily wrapped in the outer periphery of PbSO_(4) to form a product layer,hindering the mass transfer process.Therefore,it is necessary to break the PbCO_(3) product layer.In this work,the rotor stator-reinforced reactor was selected as the enhanced desulfurization reactor for the purpose of breaking the PbCO_(3) product layer and promoting mass transfer.The breakage process of the PbCO_(3) product layer generated during the PbSO_(4) desulfurization was modeled.Computational fluid dynamics simulation to the rotation conditions was carried out to theoretically analyze the fluid flow characteristics of PbSO_(4) slurry and the wall shear stress affecting the breakage of PbCO_(3) product layer.By optimizing the rotation conditions,the distribution ratio of effective rotor wall shear stress range achieved 96.1%,and the stator wall shear stress range reached 99.15%under a rotation of 2000 r·min^(-1).The research work provides a reference for analysis of the mechanism of product layer breakage in the PbSO_(4) desulfurization process,and gives a clear and intuitive systematic study on the fluid flow characteristics and wall shear stress of the desulfurization reactor.

Suiting Dynamic Models of Fixed-Bed Catalytic Reactors for Computer-Based Applications

This work investigated the applicability of heterogeneous and pseudo-homogeneous models to predict the dynamic behavior of a fixed-bed catalytic reactor. Some issues concerning the dynamic behavior of the system were discussed, such as the prediction of the inverse response phenomenon. The proposed models (Het- erogeneous I and II and Pseudo-homogeneous) were able to predict with qualitative similarity the main characteristics of the dynamic behavior of a fixed-bed catalytic reactor, including the inverse response. The computational time demanded for the solution of the heterogeneous models was 10 to 50% longer than in the case of the pseudo-homogeneous model, making the use of the former suitable for applications where computational time is not the major restriction (off-line applications). On the other hand, when on-line applications are required, the simplified model (Pseudo-homogeneous model) showed to be a good alternative because this model was able to predict (qualitatively) the dynamics of the reactor using a faster and easier numerical solution.

CFD Simulation on Ethylene Furnace Reactor Tubes

Different mathematical models for ethylene furnace reactor tubes were reviewed. On the basis of these models a new mathematical simulation approach for reactor tubes based on computational fluid dynamics （CFD） technique was presented. This approach took the flow, heat transfer, mass transfer and thermal cracking reactions in the reactor tubes into consideration. The coupled reactor model was solved with the SIMPLE algorithm. Some detailed information about the flow field, temperature field and concentration distribution in the reactor tubes was obtained, revealing the basic characteristics of the hydrodynamic phenomena and reaction behavior in the reactor tubes. The CFD approach provides the necessary information for conclusive decisions regarding the production optimization, the design and improvement of reactor tubes, and the new techniques implementation.

Numerical simulation of fixed bed reactor for oxidative coupling of methane over monolithic catalyst

A three-dimensional geometric model was set up for the oxidative coupling of methane(OCM) fixed bed reactor loaded with Na_3PO_4-Mn/SiO_2/cordierite monolithic catalyst,and an improved Stansch kinetic model was established to calculate the OCM reactions using the computational fluid dynamics method and Fluent software.The simulation conditions were completely the same with the experimental conditions that the volume velocity of the reactant is 80 ml·min^(-1) under standard state,the CH_4/O_2 ratio is 3 and the temperature and pressure is800 ℃ and 1 atm,respectively.The contour of the characteristic parameters in the catalyst bed was analyzed,such as the species mass fractions,temperature,the heat flux on side wall surface,pressure,fluid density and velocity.The results showed that the calculated values matched well with the experimental values on the conversion of CH4 and the selectivity of products(C_2H_6,C_2H_4,CO,CO_2 and H_2) in the reactor outlet with an error range of±4%.The mass fractions of CH_4 and O_2 decreased from 0.600 and 0.400 at the catalyst bed inlet to 0.445 and0.120 at the outlet,where the mass fractions of C_2H_6,C_2H_4,CO and CO_2 were 0.0245,0.0460,0.0537 and 0.116,respectively.Due to the existence of laminar boundary layer,the mass fraction contours of each species bent upwards in the vicinity of the boundary layer.The volume of OCM reaction was changing with the proceeding of reaction,and the total moles of products were greater than reactants.The flow field in the catalyst bed maintained constant temperature and pressure.The fluid density decreased gradually from 2.28 kg·m^(-3) at the inlet of the catalyst bed to 2.18 kg·m^(-3) at the outlet of the catalyst bed,while the average velocity magnitude increased from 0.108 m·s-1 to 0.120 m·s^(-1).

Numerical simulations and comparative analysis of two- and three-dimensional circulating fluidized bed reactors for CO2 capture

Carbon dioxide(CO2),the main gas emitted from fossil burning,is the primary contributor to global warming.Circulating fluidized bed reactor(CFBR)is proved as an energy-efficient method for post-combustion CO2 capture.The numerical simulation by computational fluid dynamics(CFD)is believed as a promising tool to study CO2 adsorption process in CFBR.Although three-dimensional(3D)simulations were proved to have better predicting performance with the experimental results,two-dimensional(2D)simulations have been widely reported for qualitative and quantitative studies on gas-solid behavior in CFBR for its higher computational efficiency recently.However,the discrepancies between 2D and 3D simulations have rarely been evaluated by detailed study.Considering that the differences between the 2D and 3D simulations will vary substantially with the changes of independent operating conditions,it is beneficial to lower computational costs to clarify the effects of dimensionality on the numerical CO2 adsorption runs under various operating conditions.In this work,the comparative analysis for CO2 adsorption in 2D and 3D simulations was conducted to enlighten the effects of dimensionality on the hydrodynamics and reaction behaviors,in which the separation rate,species distribution and hydrodynamic characteristics were comparatively studied for both model frames.With both accuracy and computational costs considered,the viable suggestions were provided in selecting appropriate model frame for the studies on optimization of operating conditions,which directly affect the capture and energy efficiencies of cyclic CO2 capture process in CFBR.

Large eddy simulation of unsteady flow in gas-liquid separator applied in thorium molten salt reactor

Axial gas-liquid separators have been adopted in fission gas removal systems for the development of thorium molten salt reactors. In our previous study, we observed an unsteady flow phenomenon in which the flow pattern is directly dependent on the backpressure in a gas-liquid separator; however, the underlying flow mechanism is still unknown. In order to move a step further in clarifying how the flow pattern evolves with a variation in backpressure, a large eddy simulation(LES) was adopted to study the flow field evolution. In the simulation, an artificial boundary was applied at the separator outlet under the assumption that the backpressure increases linearly. The numerical results indicate that the unsteady flow feature is captured by the LES approach, and the flow transition is mainly due to the axial velocity profile redistribution induced by the backpressure variation. With the increase in backpressure,the axial velocity near the downstream orifice transits from negative to positive. This change in the axial velocity sign forces the unstable spiral vortex to become a stable rectilinear vortex.

Numerical simulation of packed-bed reactor for oxidative coupling of methane

A three-dimensional geometric model of the oxidative coupling of methane （OCM） packed-bed reactor loaded with Na2WO4-Mn/SiO2 partic- ulate catalyst was set up, and an improved Stansch kinetic model was established to calculate the OCM reactions using the computational fluid dynamics method and Fluent software. The simulation conditions were completely the same with the experimental conditions that the volume velocity of the reactant was 80 mL/min under standard state, the ratio of CH4/O2 was 3, the temperature and pressure were 800 ℃ and 1 atm, respectively. The contour of the characteristics parameters in the catalyst bed was analyzed, such as the species mass fractions, temperature, the heat flux on side wall surface, pressure, fluid density and velocity. The results showed that the calculated values matched well with the experimental values on the conversion of CH4 and the selectivity to products （C2H6, C2H4, CO2, CO） in the reactor outlet with an error range of 4-2%. The mass fractions of CH4 and O2 decreased from 0.6 and 0.4 in the catalyst bed inlet to 0.436 and 0.142 in the outlet, where the mass fractions of C2H6, C2H4, CO and CO2 were 0.035, 0.061, 0.032 and 0.106, respectively. Due to the existence of laminar boundary layer, the contours of each component bent upwards in the vicinity of the boundary layer. This OCM reaction was volume increase reaction and the total moles of products were greater than those of reactants. The flow field in the catalyst bed maintained constant temperature and pressure. The fluid density decreased gradually from 2.28 kg/m3 in the inlet of the catalyst bed to 2.22 kg/m3 in the outlet of the catalyst bed, while the velocity increased from 0.108 m/s to 0.115 m/s.

浮动式反应堆事故气载放射性多舱输运仿真分析

浮动式反应堆受限于特殊的使用环境容易发生事故,事故后气载放射性会在舱室之间传递影响可居留性。为详细分析其事故后气载放射性在舱室之间的传递过程,利用计算流体力学方法开展了破口事故下气载放射性从堆舱中向邻舱的输运过程,对比分析了采取堆舱排风及机舱排风对气载放射性输运的控制效果。结果表明:堆舱放射性泄漏后,气载放射性经泄漏口进入机舱,局部浓度相异;排风系统在舱室内形成局部循环流,使气载放射性汇于主流经排风口排出舱室。堆舱循环流在压力容器与泄漏口之间形成气幕,阻止气载放射性迁移;机舱循环流会在泄漏口机舱侧产生指向机舱的速度,加强气载放射性向机舱的迁移。同时采用堆舱及机舱排风在排风时间达到180 s时可使机舱气载放射性浓度相比无通风情况下降92.5%。

导流筒结构对气升式反应器传质性能的影响研究

气升式环流反应器广泛应用于化工、环境等领域,深入研究反应器内气-液两相流体流动行为对提高其传质性能具有重要意义。通过分别建立气-液两相流模型和气泡粒群衡算模型并实现二者的耦合求解,研究了单个方形导流筒、单个圆形导流筒和6个圆形导流筒结构对气-液两相流体流动特性、气泡尺寸分布和气-液相间传质的影响。研究表明,含6个圆形导流筒结构的气升式环流反应器气含率和液相速度分布趋于均匀,平均气含率更大,气泡尺寸更小,传质速率更大,反应器的综合性能得到显著提升。相关模拟结果为气升式环流反应器结构优化和放大指明了方向。

桥臂电抗器的温升仿真计算方法对比研究

本文作者以柔性直流输电系统中的桥臂电抗器为研究对象,建立了油浸式桥臂电抗器的三维温升仿真模型,分析了在设计参数下桥臂电抗器内部的流场和温升,并与专业软件SAPRTON仿真结果进行了对比,验证了仿真方法的适用性。

Microfluidic field strategy for enhancement and scale up of liquid-liquid homogeneous chemical processes by optimization of 3D spiral baffle structure

Due to the scale effect, the uniform distribution of reagents in continuous flow reactor becomes bad when the channel is enlarged to tens of millimeters. Microfluidic field strategy was proposed to produce high mixing efficiency in large-scale channel. A 3D spiral baffle structure(3SBS) was designed and optimized to form microfluidic field disturbed by continuous secondary flow in millimeter scale Y-shaped tube mixer(YSTM). Enhancement effect of the 3SBS in liquid-liquid homogeneous chemical processes was verified and evaluated through the combination of simulation and experiment. Compared with 1 mm YSTM, 10 mm YSTM with 3SBS increased the treatment capacity by 100 times, shortened the basic complete mixing time by 0.85 times, which proves the potential of microfluidic field strategy in enhancement and scale-up of liquid-liquid homogeneous chemical process.

渗透汽化-酯化反应耦合生产乙酸乙酯过程模拟与分析

为了解决乙酸乙酯生产过程中转化率低的问题,提出渗透汽化-酯化反应耦合技术。首先利用Aspen Custom Modeler(ACM)软件建立内置式连续性渗化膜反应器(PVMR)模型并进行验证,然后利用Aspen Plus考察反应温度、进料酸醇比、膜面积与反应液体积比对PVMR过程性能的影响。结果表明,乙醇转化率增量与反应温度之间呈正相关性;随着进料酸醇比增大,乙醇转化率增量呈先增大后减小趋势;增加膜面积与反应液体积比能促进PVMR性能。在反应温度90℃,进料酸醇比为2,膜面积与反应液体积比为100 m^(-1)时,PVMR过程乙醇转化率为82.4%。研究结果为PVMR生产乙酸乙酯节能集成工艺开发提供基础和参考。

中低温煤焦油加氢反应器不同分配器中液体分布的CFD模拟

中低温煤焦油(LTCT)是一种高密度、高黏度的重质油品,加氢处理是对其清洁化利用的重要手段,其过程主要在滴流床反应器(TBR)内完成。气液分配器作为TBR中的重要部件,影响着反应器中催化剂床层的表现。本文建立了基于Euler-Euler方法的计算流体力学(CFD)模型,并根据已报道的文献冷模实验结果完成模型验证,对LTCT和氢气在4种分配器(泡罩型、多孔烟囱型、齿缝烟囱型和气提管型)中的流动进行了模拟,对比分析了分配器液相的分布、流动行为以及进出口压降;并且引入液体分布不均匀度(M_(f))概念,对4种分配器的气液分配效果进行了定量评价。结果表明,LTCT通过泡罩型分配器后的液相覆盖范围最广;泡罩型分配器在y=-200mm截面处Mf为0.13,分配效果最好,且气液两相流集中现象不严重。

反冲释放对反应堆活化腐蚀产物源项的影响研究

中子与靶核碰撞时引起的靶核反冲释放,对于反应堆活化腐蚀产物源项分析有非常重要的影响。对于使用水冷方式的反应堆,在辐照区反冲释放可使活化腐蚀产物离开壁面进入到冷却剂中,并随冷却剂迁移到非辐照区,使非辐照区的设备也带有放射性。本文研究了反冲释放在反应堆内的作用方式,建立了反冲释放的计算模型和程序模块,并集成到活化腐蚀产物源项分析程序CATE中,利用改进后的CATE程序,计算分析了堆芯与蒸汽发生器中主要的活化腐蚀产物核素^(58)Co与^(60)Co在考虑反冲释放前后的数值,明确了反冲释放效应的影响程度。计算结果表明:考虑反冲释放前后堆芯处^(58)Co与^(60)Co活度的比值有所下降,而在蒸汽发生器中的比值则有所上升;反冲释放的总作用概率与腐蚀产物层厚度相关,会随着反应堆的运行而逐渐降低,反应堆运行初期作用概率的数量级在10^(-1),对活化腐蚀产物的迁移有显著影响,100 d后作用概率的数量级下降到10^(-3),对活化腐蚀产物源项的影响较小。

甲醇反应器的CFD模拟与换热优化

混合气制备甲醇是目前较为常用的工业生产甲醇方法,利用CFD软件模拟甲醇的固定床反应器,在Fluent中输入主副反应的动力学,得到模拟结果并针对该强放热反应提出设备换热上的优化方案,在提高甲醇产量的同时,保证反应器内部有较高的正向反应速率。

基于数值模拟的SCR脱硝反应器流场优化

为优化选择性催化还原(SCR)脱硝反应器的流场,采用了组合优化方案;在反应器入口处设置多孔板,在反应器内部设置渐扩口式、格栅式、弧板式共三种导流板;采用计算流体力学(CFD)进行数值模拟获得反应器内部流场,进行对比研究。研究发现:多孔板孔距与孔径比为1.2时,压降较小且能获得较好的流场均布性能;基于反应器结构特点设计的导流板能获得较好的优化效果;催化剂具有流场均布能力,催化剂多层布置可有效改善第一层之后的床层流场,但同时会增大压降;通过组合导流方案,第一层催化剂床层的流速相对标准偏差(RSD)从7.16%降为2.51%,并改善了湍动能的耗散。研究结果对SCR反应器的导流件设计具有一定指导意义。

基于MATLAB的磁饱和式可控电抗器的仿真模型参数及过渡时间分析

建模仿真方法和过渡时间计算是磁饱和式可控电抗器研究中值得关注的2个重要问题。根据磁饱和式可控电抗器的饱和特性,通过对小斜率磁化特性的分析,找到了电抗器额定容量、额定电压、自耦比和绕组电阻之间的定量关系,明确了基于MATLAB的磁饱和式可控电抗器仿真模型参数的设置方法。通过对小斜率磁化特性的分段线性化,把从空载到满载的过渡过程分为直流磁链随时间线性增加和控制电流根据线性RL电路充电规律变化这2个过程,得到了比较准确的过渡时间计算公式。实例仿真结果说明所提分析方法简捷有效。

翼形桨搅拌槽内混合过程的数值模拟

采用FLUENT软件的多重参考系(MRF)及标准k-ε模型,将速度场与浓度场方程分开进行求解,对单层轴流式三叶CBY翼形桨搅拌槽内的混合过程进行了数值模拟,所得的混合时间的模拟结果与实验值相吻合。同时采用数值模拟的方法研究了不同的示踪剂加料点、监测点位置及操作条件对混合时间的影响规律;模拟结果表明,混合过程主要由搅拌槽内的流体流动所控制,混合时间与示踪剂加料点及监测点位置密切相关。上述的研究结果对于工业搅拌反应器的优化具有一定的参考意义。