Biomass gasification in supercritical and subcritical water: The effect of the reactor material

Daniele Castello; Andrea Kruse; Luca Fiori

doi:10.1016/j.cej.2013.04.119

Biomass gasification in supercritical and subcritical water: The effect of the reactor material

Daniele Castello, Andrea Kruse, Luca Fiori^*

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

56 Citations (Scopus)

Abstract

Batch reactors made of stainless steel and Inconel® 625 were used for the hydrothermal gasification of glucose and beech sawdust under both subcritical (350°C) and supercritical (400°C) conditions at a pressure of 30MPa. These tests were executed over residence times ranging from 60 to 300min. The amounts of solid, liquid and gas produced and the composition of the resulting gas phase were measured. The results showed that a higher H2 output was achieved in the stainless steel reactors, while the Inconel® 625 reactors were more effective for the synthesis of CH4 and light hydrocarbons. A visual observation of the metal surfaces was performed using scanning electron microscopy to explain the persistence of catalytic activity even after an aging treatment and many hours of operation.

Original language	English
Journal	Chemical engineering journal
Volume	228
Pages (from-to)	535-544
Number of pages	10
ISSN	1385-8947
DOIs	https://doi.org/10.1016/j.cej.2013.04.119
Publication status	Published - Jul 2013
Externally published	Yes

Keywords

Hydrothermal conversion
Reactor material
Supercritical water gasification

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title = "Biomass gasification in supercritical and subcritical water: The effect of the reactor material",

abstract = "Batch reactors made of stainless steel and Inconel{\textregistered} 625 were used for the hydrothermal gasification of glucose and beech sawdust under both subcritical (350°C) and supercritical (400°C) conditions at a pressure of 30MPa. These tests were executed over residence times ranging from 60 to 300min. The amounts of solid, liquid and gas produced and the composition of the resulting gas phase were measured. The results showed that a higher H2 output was achieved in the stainless steel reactors, while the Inconel{\textregistered} 625 reactors were more effective for the synthesis of CH4 and light hydrocarbons. A visual observation of the metal surfaces was performed using scanning electron microscopy to explain the persistence of catalytic activity even after an aging treatment and many hours of operation.",

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T1 - Biomass gasification in supercritical and subcritical water

T2 - The effect of the reactor material

AU - Castello, Daniele

AU - Kruse, Andrea

AU - Fiori, Luca

PY - 2013/7

Y1 - 2013/7

N2 - Batch reactors made of stainless steel and Inconel® 625 were used for the hydrothermal gasification of glucose and beech sawdust under both subcritical (350°C) and supercritical (400°C) conditions at a pressure of 30MPa. These tests were executed over residence times ranging from 60 to 300min. The amounts of solid, liquid and gas produced and the composition of the resulting gas phase were measured. The results showed that a higher H2 output was achieved in the stainless steel reactors, while the Inconel® 625 reactors were more effective for the synthesis of CH4 and light hydrocarbons. A visual observation of the metal surfaces was performed using scanning electron microscopy to explain the persistence of catalytic activity even after an aging treatment and many hours of operation.

AB - Batch reactors made of stainless steel and Inconel® 625 were used for the hydrothermal gasification of glucose and beech sawdust under both subcritical (350°C) and supercritical (400°C) conditions at a pressure of 30MPa. These tests were executed over residence times ranging from 60 to 300min. The amounts of solid, liquid and gas produced and the composition of the resulting gas phase were measured. The results showed that a higher H2 output was achieved in the stainless steel reactors, while the Inconel® 625 reactors were more effective for the synthesis of CH4 and light hydrocarbons. A visual observation of the metal surfaces was performed using scanning electron microscopy to explain the persistence of catalytic activity even after an aging treatment and many hours of operation.

KW - Hydrothermal conversion

KW - Reactor material

KW - Supercritical water gasification

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DO - 10.1016/j.cej.2013.04.119

M3 - Journal article

AN - SCOPUS:84878930160

SN - 1385-8947

VL - 228

SP - 535

EP - 544

JO - Chemical engineering journal

JF - Chemical engineering journal

ER -

Biomass gasification in supercritical and subcritical water: The effect of the reactor material

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Keywords

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