Micro Scale Heat Transfer Comparison between Packed Beds and Microfibrous Entrapped Catalysts

Sheng, Min; Gonzalez, Carlos F.; Yantz, William R.; Cahela, Donald R.; Yang, Huihua; Harris, Daniel R.; Tatarchuk, Bruce J.

doi:10.1080/19942060.2013.11015486

Cited by 5 publications

(9 citation statements)

References 21 publications

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“…For the MFECC bed, the maximum temperature at the centerline of the reactor remains almost constant under all GHSV conditions (5000 h −1 to 10,000 h −1 ) at 534.5 K. Therefore, operating at higher velocities induces very small changes in the thermal behavior of the MFECC bed. The observations in the thermal behavior of both the PBR and MFECC discussed above are also supported by a modeling study conducted by Sheng et al, who conducted a microscale heat transfer comparison between a PBR and an MFECC bed in a stagnant gas and flowing nitrogen gas conditions [62]. They reported that 97.2% of the total heat flux transferred within the MFECC bed was found to be transported by the continuous metal fibers.…”

Section: Effect Of Varying the Ghsvsupporting

confidence: 64%

Thermal Assessment of a Micro Fibrous Fischer Tropsch Fixed Bed Reactor Using Computational Fluid Dynamics

et al. 2020

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A two-dimensional (2D) Computational Fluid Dynamics (CFD) scale-up model of the Fischer Tropsch reactor was developed to thermally compare the Microfibrous-Entrapped-Cobalt-Catalyst (MFECC) and the conventional Packed Bed Reactor (PBR). The model implements an advanced predictive detailed kinetic model to study the effect of a thermal runaway on C5+ hydrocarbon product selectivity. Results demonstrate the superior capability of the MFECC bed in mitigating hotspot formation due to its ultra-high thermal conductivity. Furthermore, a process intensification study for radial scale-up of the reactor bed from 15 mm internal diameter (ID) to 102 mm ID demonstrated that large tube diameters in PBR lead to temperature runaway >200 K corresponding to >90% CO conversion at 100% methane selectivity, which is highly undesirable. While the MFECC bed hotspot temperature corresponded to <10 K at >30% CO conversion, attributing to significantly high thermal conductivity of the MFECC bed. Moreover, a noticeable improvement in C5+ hydrocarbon selectivity >70% was observed in the MFECC bed in contrast to a significantly low number for the PBR (<5%).

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Section: Effect Of Varying the Ghsvsupporting

confidence: 64%

Thermal Assessment of a Micro Fibrous Fischer Tropsch Fixed Bed Reactor Using Computational Fluid Dynamics

et al. 2020

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“…The radial temperature distribution was mostly uniform along the radial direction, with a large temperature gradient near the reactor wall (Figure ). Compared with that of the packed-bed reactor, the temperature difference between the centerline and the near-wall region was at least 100 times smaller for the MFEC reactor than the packed-bed reactor running at even lower face velocity . The majority of catalyst particles remained in a small temperature range for the MFEC reactor because of the uniform temperature distribution, whereas only a small portion of the catalyst was at the desired temperature for the packed bed .…”

Section: Resultsmentioning

confidence: 95%

“…The temperature distribution profile for any reactive structure that operates at high velocity can be calculated by numerically solving the equation with adjusted axial and radial thermal conductivities. Sheng et al experimentally and theoretically studied the temperature distribution in packed beds during highly exothermic reactions . The radial temperature distribution was found to exhibit a large gradient between the centerline and the near-wall region because of the poor effective thermal conductivity of packed beds.…”

Section: Resultsmentioning

confidence: 99%

Comparison of Packed Beds, Washcoated Monoliths, and Microfibrous Entrapped Catalysts for Ozone Decomposition at High Volumetric Flow Rates in Pressurized Systems

Zhao

Henderson

et al. 2016

Ind. Eng. Chem. Res.

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Weight- and volume-sensitive systems such as aircraft require restrictive ducting, which leads to high face velocities (10–40 m/s) in reactive structures. A head-to-head comparison was conducted experimentally among packed beds (estimated data), monoliths, and microfibrous entrapped catalysts (MFECs) during ozone decomposition to investigate the effects of system pressure on the effective reaction rate, gas–solid mass-transfer rate, and heterogeneous contacting efficiency (HCE, the ratio of the logarithmic ozone removal to the pressure drop across the reactor). For the same mass flow rate, higher-pressure systems (2–3 atm) operate at lower face velocities than atmospheric-pressure systems. These higher system pressures result in increased residence times and reaction rates; therefore, HCE is enhanced. In addition, the HCE for the MFEC was more than twice that of the packed bed or monolith at equivalent system pressures because of the higher gas–solid mass-transfer rates and reduced pressure drops of the MFEC.

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“…This was also concluded by Zhu et al (2007Zhu et al ( , 2008) during a review on particulate flows modelled with the CCDM approach. Based on this approach Sheng et al (2013) investigated into the micro-scale heat transfer of packed beds and micro-fibrous entrapped catalysts and concluded that the thermal resistance of the contact points account for more than 90 % of the total resistance. Similarly, Kon et al (2013) modelled the liquid flow in the lower part of a blast furnace by the MPS method.…”

Section: Introductionmentioning

confidence: 99%

“…CCDM has seen a mayor development in last two decades and describes motion of the solid phase by the Discrete Element Method (DEM) on an individual particle scale and the remaining phases are treated by the Navier-Stokes equations. However, current CCDM approaches should be extended to a truly multi-phase flow behaviour as opposed to the Volume-of-Fluid method and the multi-phase mixture model stated by Sheng (2013). Furthermore, particle shapes other than spherical geometries have to be taken into account to meet engineering needs according to Zhu et al (2007Zhu et al ( , 2008.…”

Section: Introductionmentioning

confidence: 99%

An Integral Approach to Multi-physics Application for Packed Bed Reactors

Peters

Besseron

Estupinan

et al. 2014

Computer Aided Chemical Engineering

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A large number of engineering applications involve granular material or a particulate phase in combination with a gaseous or liquid phase. Predominant applications are as diverse as pharmaceutical industry e.g. drug production, agriculture food and processing industry, mining, construction and agricultural machinery, metals manufacturing, energy production and systems biology. Common to all these application is that they cover a large spectrum of length scales ranging from inner particle length scales to global dimensions of the reactor. In order to describe the processes and their interaction accurately, tailored algorithms are required for prediction and analysis. The current numerical approach of the Extended Discrete Element Method (XDEM) is based on an Eulerian-Lagrange coupling. For this purpose the solid phase consisting of individual particles is treated by the Lagrange method that describes both the dynamic state i.e. position and orientation of each particle in space and time and its thermodynamic state e.g. internal temperature and species distribution. The flow of gas in the void space between the particles is predicted by traditional and well-proven Computational Fluid Dynamics (CFD) taking into account heat and mass transfer between the particles and the surrounding gas phase. Hence, the entire process represented by the sum of all particle processes in conjunction with fluid dynamics. The afore-mentioned numerical concept was applied to predict pyrolysis of a packed bed of wood particles in a cylindrical reactor. A comparison of predicted results with experimental data show good agreement. Hence, the numerical concept is able to resolve a large range of length scales for solid reaction engineering. An analysis of detailed results helps to uncover the underlying physics of the process, and thus, allows for an improved design and operation conditions.

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Micro Scale Heat Transfer Comparison between Packed Beds and Microfibrous Entrapped Catalysts

Cited by 5 publications

References 21 publications

Thermal Assessment of a Micro Fibrous Fischer Tropsch Fixed Bed Reactor Using Computational Fluid Dynamics

Thermal Assessment of a Micro Fibrous Fischer Tropsch Fixed Bed Reactor Using Computational Fluid Dynamics

Comparison of Packed Beds, Washcoated Monoliths, and Microfibrous Entrapped Catalysts for Ozone Decomposition at High Volumetric Flow Rates in Pressurized Systems

An Integral Approach to Multi-physics Application for Packed Bed Reactors

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