Catalyst Heating Characteristics in the Traveling-Wave Microwave Reactor

Traveling-Wave Microwave Reactor (TMR) presents a novel heterogeneous catalytic reactor concept based on a coaxial waveguide structure. In the current paper, both modeling and experimental studies of catalyst heating in the TMR are presented. The developed 3D multiphysics model was validated from the electromagnetic and heat transfer points of view. Extrudes of silicon carbide (SiC) were selected as catalyst supports and microwave absorbing media in a packed-bed configuration. The packed-bed temperature evolution was in good agreement with experimental data, with an average deviation of less than 10%. Both experimental and simulation results show that the homogeneous temperature distribution is possible in the TMR system. It is envisioned that the TMR concept may facilitate process scale-up while providing temperature homogeneity beyond the intrinsic restrictions of microwave cavity systems.

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Packed-Bed Removal of Copper and Zinc Ions Using Chemically-Treated Chicken Feathers

Energy & Environment ◽

10.1260/095830503322364467 ◽

2003 ◽

Vol 14 (4) ◽

pp. 461-472 ◽

Cited By ~ 1

Author(s):

Sameer Al-Asheh ◽

Fawzi Banat

Keyword(s):

Scale Up ◽

Packed Bed ◽

Sorption Process ◽

Design Parameters ◽

Zinc Ions ◽

Chicken Feathers ◽

Copper And Zinc ◽

Chemically Treated ◽

Process Scale Up ◽

Bed Capacity

In this work, the sorption of copper by chemically treated chicken feathers was tested via packed-bed column. Chicken feathers were selected as adsorbent based on its high availability as environmental waste. The alkaline-treated chicken feathers column showed good sorption capacity toward copper and zinc ions. It was proved that an increase in metal concentration or flow rate of the influent solution shortens the break-through time. The break-through time increased with the bed depth. The break-through time occurred earlier when zinc was passed through the column rather than copper, but the bed capacity was higher for the later than for the former. The key process design parameters, which could serve as a basis for sorption process scale up, were calculated by applying the Bed-Depth-Service-Time (BDST) model to the experimental data.

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PENGGUNAAN AIR SUPER KRITIS PADA DEPOLIMERISASI NYLON-12 (BATCH PROCESS)

Jurnal Rekayasa Lingkungan ◽

10.29122/jrl.v5i3.1901 ◽

2018 ◽

Vol 5 (3) ◽

Author(s):

Mohamad Yusman

Keyword(s):

Supercritical Water ◽

Scale Up ◽

Experimental Studies ◽

Reaction System ◽

Batch Process ◽

Chemical Recycling ◽

Water Decomposition ◽

Product Distributions ◽

New Process ◽

Nylon 12

Water at the supercritical state is a new process for the chemical recycling. At this thermodynamic state i.e. Pc = 218 atmospheres and Tc = 374oC , water behaves very differently from its everyday temperament and it is a very good solvent for organic components. Experimental studies show that supercritical water can decompose hydrocarbons/polymers and produce useful products like 2-Azacyclotridecanone /lactam-1 from Nylon-12 (batch process). The decomposition process itself was carried out in batch reaction system in order to get more information about product distributions, time dependence, and scale-up possibilities.Keywords: supercritical water, decomposition, batch, polymer, hydrocarbon

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Design of a continuous flow immobilized-cell reactor for biosynthetical production of L-aspartic acid

Collection of Czechoslovak Chemical Communications ◽

10.1135/cccc19852122 ◽

1985 ◽

Vol 50 (10) ◽

pp. 2122-2133 ◽

Cited By ~ 2

Author(s):

Jindřich Zahradník ◽

Marie Fialová ◽

Jan Škoda ◽

Helena Škodová

Keyword(s):

Aspartic Acid ◽

Continuous Flow ◽

Immobilized Cells ◽

Scale Up ◽

Fixed Bed ◽

Packed Bed ◽

Fixed Bed Reactor ◽

Experimental Program ◽

Design Parameters ◽

Immobilized Cell

An experimental study was carried out aimed at establishing a data base for an optimum design of a continuous flow fixed-bed reactor for biotransformation of ammonium fumarate to L-aspartic acid catalyzed by immobilized cells of the strain Escherichia alcalescens dispar group. The experimental program included studies of the effect of reactor geometry, catalytic particle size, and packed bed arrangement on reactor hydrodynamics and on the rate of substrate conversion. An expression for the effective reaction rate was derived including the effect of mass transfer and conditions of the safe conversion-data scale-up were defined. Suggestions for the design of a pilot plant reactor (100 t/year) were formulated and decisive design parameters of such reactor were estimated for several variants of problem formulation.

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