Supercritical water gasification: practical design strategies and operational challenges for lab-scale, continuous flow reactors

Pinkard, Brian R.; Gorman, Dean R.; Tiwari, Kartik; Rasmussen, Elizabeth; Kramlich, John C.; Reinhall, Per G.; Novosselov, Igor

doi:10.1016/j.heliyon.2019.e01269

Cited by 70 publications

(47 citation statements)

References 105 publications

(298 reference statements)

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“…Achieving high temperatures and pressures, mitigating corrosion of reactor components, rapid heating and quenching of the reagent, acquiring accurate experimental data, and strategies for achieving a well-mixed, uniform flow must all be considered in the design of a supercritical water reactor for studies of reaction chemistry. Solutions for mitigating some of these challenges have been reported in the literature, but open questions remain regarding the best methods to mitigate char formation and salt precipitation in reactors designed to process complex feedstocks [3].…”

Section: Continuous Supercritical Water Reactors For Investigating Rementioning

confidence: 99%

“…The most reliable way to achieve independent pressure and mass flow control in a continuous SCWR is to operate a constant flow rate pump(s) in series with a back pressure regulator (BPR). Spring-loaded or dome-loaded BPRs are simple to use and reliable [3,5]. High-performance liquid chromatography (HPLC) pumps are often used for pumping liquid reagents to high pressures with precise flow rate control in the range of 0.01-30 mL/min [6][7][8][9].…”

Section: Heating and Pressurizationmentioning

confidence: 99%

“…However, some researchers prefer to report the total organic carbon (TOC) concentration in the liquid phase by using a TOC analyzer, which is sufficient for calculating carbon CE. Occasionally solid products are analyzed ex situ, using scanning electron microscopy (SEM), proton-induced X-ray emission (PIXE), Raman spectroscopy, or FTIR spectroscopy [3].…”

Section: Reactor Monitoring and Data Acquisitionmentioning

confidence: 99%

“…It is beyond the scope of this chapter to review the body of work investigating various catalysts for SCWG. We direct the reader to the comprehensive reviews on the subject [2,3]. However, it is worth mentioning some broad findings from this extensive area of research.…”

Section: Gasification Catalystsmentioning

confidence: 99%

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Gasification Kinetics in Continuous Supercritical Water Reactors

Pinkard¹,

Kramlich²,

Reinhall³

et al. 2020

Advanced Supercritical Fluids Technologies

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Supercritical water gasification (SCWG) is an emerging technology with synergistic applications in renewable energy and waste processing. Supercritical water (SCW) functions as a green reaction medium during the gasification process, serving to dissolve and decompose complex organic molecules via ionic, radical, hydrolysis, and pyrolysis reaction mechanisms. Researchers investigate the decomposition of model compounds in order to predict product yields and conversion efficiencies during the gasification of heterogeneous biomass waste, food waste, sewage sludge, and other available feedstocks. Continuous, laboratory-scale reactors are often employed to study reaction kinetics, pathways, and mechanisms. This chapter synthesizes previous work investigating model compound gasification in continuous supercritical water reactors (SCWRs). A summary of continuous reactor design strategies is presented for practical benefit, followed by a discussion on reaction chemistry in the supercritical water environment. Reaction pathways and mechanisms have been investigated for several model compounds, lending insight toward the conditions needed for the complete conversion of real-world feedstocks. Several studies assume first-order reaction kinetics and propose Arrhenius parameters for the decomposition reaction. The first-order rate assumption must be carefully evaluated, and the applicable temperature range must be specified. Opportunities for further research are discussed.

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Section: Continuous Supercritical Water Reactors For Investigating Rementioning

confidence: 99%

Section: Heating and Pressurizationmentioning

confidence: 99%

Section: Reactor Monitoring and Data Acquisitionmentioning

confidence: 99%

Section: Gasification Catalystsmentioning

confidence: 99%

See 2 more Smart Citations

Gasification Kinetics in Continuous Supercritical Water Reactors

Pinkard¹,

Kramlich²,

Reinhall³

et al. 2020

Advanced Supercritical Fluids Technologies

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“…Heating of the reactor section is typically accomplished by a combination of (i) external heating (e.g., with a radiant furnace), (ii) internal heating from the fuel value of the feedstock, and/or (iii) internal heating with a pilot fuel (e.g., diesel, ethanol, isopropanol, etc.). 21 Note that "pilot" can also be considered as co-fuel; the need for its use depends on the heating value of the waste stream.…”

Section: Introductionmentioning

confidence: 99%

Design of a Small-Scale Supercritical Water Oxidation Reactor. Part I: Experimental Performance and Characterization

Moore¹,

Pinkard

Purohit³

et al. 2020

Preprint

Self Cite

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A small-scale supercritical water oxidation reactor is designed and fabricated to study the destruction of hazardous wastes. The downward bulk flow is heated with the introduction of pilot fuel (ethanol/water mixture), and oxidant (H2O2/water mixture). Both streams are introduced coaxially. The fuel dilution is varied from 2 to 7 mol% ethanol/water, and the oxidant-to-fuel stoichiometric equivalence ratio (ΦAF), is varied from 1.1 to 1.5. Higher ethanol concentrations in the pilot fuel stream and operation near-stoichiometric results in a more stratified temperature profile, i.e., highest local fluid temperatures near the top and the lowest temperatures at the bottom of the reactor. Steady operation at 603.5 °C is achieved with a nominal residence time of 25.3 s at 7 mol% fuel dilution and ΦAF of 1.1. At the lowest pilot fuel dilution (2 mol%), the temperature profile is nearly uniform, approaching a distributed reaction regime.

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Towards Negative Emissions: Hydrothermal Carbonization of Biomass for Sustainable Carbon Materials

Yu,

He,

Zhang

et al. 2024

Advanced Materials

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The contemporary production of carbon materials heavily relies on fossil fuels, contributing significantly to the greenhouse effect. Biomass is a carbon‐neutral resource whose organic carbon is formed from atmospheric CO2. Employing biomass as a precursor for synthetic carbon materials can fix atmospheric CO2 into solid materials, achieving negative carbon emissions. Hydrothermal carbonization (HTC) presents an attractive method for converting biomass into carbon materials, by which biomass can be transformed into materials with favorable properties in a distinct hydrothermal environment, and these carbon materials have made extensive progress in many fields. However, the HTC of biomass is a complex and interdisciplinary problem, involving simultaneously the physical properties of the underlying biomass and sub/supercritical water, the chemical mechanisms of hydrothermal synthesis, diverse applications of resulting carbon materials, and the sustainability of the entire technological routes. This review starts with the analysis of biomass composition and distinctive characteristics of the hydrothermal environment. Then, the factors influencing the HTC of biomass, the reaction mechanism, and the properties of resulting carbon materials are discussed in depth, especially the different formation mechanisms of primary and secondary hydrochars. Furthermore, the application and sustainability of biomass‐derived carbon materials are summarized, and some insights into future directions are provided.This article is protected by copyright. All rights reserved

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Supercritical water gasification: practical design strategies and operational challenges for lab-scale, continuous flow reactors

Cited by 70 publications

References 105 publications

Gasification Kinetics in Continuous Supercritical Water Reactors

Gasification Kinetics in Continuous Supercritical Water Reactors

Design of a Small-Scale Supercritical Water Oxidation Reactor. Part I: Experimental Performance and Characterization

Towards Negative Emissions: Hydrothermal Carbonization of Biomass for Sustainable Carbon Materials

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