Impact of a draft tube on industrial‐scale Fluid Coker™ Spray Jets in fluidized beds

ZirGachian, M. Ali; Briens, Cédric; Berruti, Franco; McMillan, Jennifer

doi:10.1002/cjce.23063

Cited by 5 publications

(2 citation statements)

References 19 publications

(42 reference statements)

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“…Enhancing radial mixing can therefore promote interactions between droplets and particles . This can be achieved by confining the jet with a draft tube located downstream of the spray nozzle tip. ,− The distance from the nozzle tip should be such as to allow for sufficient particle entrainment into the jet cavity. ,, The entrainment of particles into the jet can also be improved by modifying the draft tube geometry . Although a draft tube will reduce particle entrainment into the jet, therefore increasing the average liquid content of the wet solids formed at the tip of the jet, its beneficial impact results from the reduction of variations in liquid content within the wet solids; CFD modeling confirmed that a draft tube reduces the amount of the wettest agglomerates, which are the most resistant to breakup in the fluidized bed. , Draft tubes have also been shown to improve the liquid distribution with vertical spray jets…”

Section: Reactormentioning

confidence: 99%

Review of Research Related to Fluid Cokers

Briens

McMillan

2021

Energy Fuels

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Fluid coking is a thermal conversion process that uses a conventional two-vessel circulating fluidized bed to convert heavy hydrocarbon feeds to lighter products. The technology was developed in the 1950s and since then has been used commercially around the world to upgrade heavy oils from various sources. Research work has been summarized related to all aspects of the fluid coking process, including reaction fundamentals, bed hydrodynamics, liquid distribution and jet–bed interaction, mixing of solid particles and agglomerates, mixing of vapors, control of the particle size, cleaning of the vapor stream in the scrubber, cleaning of the cold coke in the stripper, process monitoring, coke transfer lines, and the burner. The fluid coking process involves complex interactions between fluidized bed hydrodynamics, liquid feed injection, and reaction kinetics, and research tools that can take into account all of these interacting variables are requited to test methods to optimize the process. Fluid cokers can process many different types of feeds, and future applications may include blending and co-processing a variety of feedstocks ranging from waste plastics, pyrolytic bio-oil, and off-spec vegetable oils with heavy oil. The findings from this summary are also relevant for other applications that inject liquid into fluidized beds, such as the fluid catalytic cracking process, olefin polymerization cooled by liquid injection, granulators, and coaters.

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Section: Reactormentioning

confidence: 99%

Review of Research Related to Fluid Cokers

Briens

McMillan

2021

Energy Fuels

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“…[27][28][29][30][31][32][33][34] Agglomeration also occurs, even with spray nozzles that generate tiny droplets, when the bed solids on which the droplets impact are not renewed fast enough; agglomerate formation can be reduced by increasing the fluidization velocity, redirecting gas bubbles to the spray jet cavity, [35] or changing the particle mixing in the spray region. [36][37][38][39][40] Laboratory experiments suggest that the benefits of a better nozzle design and better local bed hydrodynamics complement each other. [41] Finally, agglomeration is more likely to occur when the sprayed liquid wets particles more effectively, that is, when wettability is increased.…”

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confidence: 99%

Experimental study of liquid vaporization in a fluidized bed

et al. 2022

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Liquid injection into a gas-solid fluidized bed has been applied in various industries, such as coating and granulation processes in pharmaceutical and food industries, reactor cooling in polyolefin production, fluid catalytic cracking, and fluid coking in the petroleum industry. A new experimental method has been successfully developed to monitor the vaporization rate of a liquid injected into a fluidized bed. In addition, it can be used to determine the mass of liquid accumulated in the bed at a steady state. With this new method, measurements have identified three phenomena that may increase the amount of liquid accumulated at steady state in a fluidized bed. (1) Gas mixing affects vaporization when the bed temperature is lower than the liquid boiling point. In liquid-rich regions of the bed, local vapour may build up, limiting the vaporization rate. Consequently, suitable emulsion to bubble gas transfer reduces the amount of accumulated liquid. (2) Solids mixing: hot particles from the rest of the bed must mix with the wetted particles to provide enough heat for vaporization. Good solids mixing reduces the amount of accumulated liquid.(3) Wet agglomerates formation: liquid trapped within wet agglomerates takes much longer to vaporize. The amount of accumulated liquid can be reduced by injecting the liquid in a well-agitated bed region, operating at a higher bed temperature, or increasing the flowrate of atomization gas.

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Jets in Fluidized Beds

Briens

McMillan

2020

Essentials of Fluidization Technology

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Impact of a draft tube on industrial‐scale Fluid Coker™ Spray Jets in fluidized beds

Cited by 5 publications

References 19 publications

Review of Research Related to Fluid Cokers

Review of Research Related to Fluid Cokers

Experimental study of liquid vaporization in a fluidized bed

Jets in Fluidized Beds

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