Supercritical water gasification (SCWG) is an emerging technology for the valorization of (wet) biomass into a valuable fuel gas composed of hydrogen and/or methane. The harsh temperature and pressure conditions involved in SCWG (T > 375 °C, P > 22 MPa) are definitely a challenge for the manufacturing of the reactors. Metal surfaces are indeed subject to corrosion under hydrothermal conditions and expensive special alloys are needed to overcome such drawback. A ceramic reactor could be a potential solution to this issue. Finding a suitable material is however complex, because the catalytic effect of the material can influence the gas yield and composition. In this work, a research reactor featuring an internal alumina inlay was utilized to conduct long-time (16 h) batch tests with real biomasses and model compounds. The same experiments were also conducted in batch reactors made of stainless steel and Inconel 625. The results show that the three devices have similar performance patterns in terms of gas production, although in the ceramic reactor higher yields of C2+ hydrocarbons were obtained. The SEM observation of the reacted alumina surface revealed a good resistance of such material to supercritical conditions, even though some intergranular corrosion was observed.
Supercritical water gasification of biomass in a ceramic reactor: long-time batch experiments / Castello, Daniele; Rolli, Birgit; Kruse, Andrea; Fiori, Luca. - In: ENERGIES. - ISSN 1996-1073. - STAMPA. - 2017:10(2017), p. 1734. [10.3390/en10111734]
Supercritical water gasification of biomass in a ceramic reactor: long-time batch experiments
Daniele Castello;Luca Fiori
2017-01-01
Abstract
Supercritical water gasification (SCWG) is an emerging technology for the valorization of (wet) biomass into a valuable fuel gas composed of hydrogen and/or methane. The harsh temperature and pressure conditions involved in SCWG (T > 375 °C, P > 22 MPa) are definitely a challenge for the manufacturing of the reactors. Metal surfaces are indeed subject to corrosion under hydrothermal conditions and expensive special alloys are needed to overcome such drawback. A ceramic reactor could be a potential solution to this issue. Finding a suitable material is however complex, because the catalytic effect of the material can influence the gas yield and composition. In this work, a research reactor featuring an internal alumina inlay was utilized to conduct long-time (16 h) batch tests with real biomasses and model compounds. The same experiments were also conducted in batch reactors made of stainless steel and Inconel 625. The results show that the three devices have similar performance patterns in terms of gas production, although in the ceramic reactor higher yields of C2+ hydrocarbons were obtained. The SEM observation of the reacted alumina surface revealed a good resistance of such material to supercritical conditions, even though some intergranular corrosion was observed.File | Dimensione | Formato | |
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