Energy Transformation: Assessment of Urban Lignocellulosic Biomass Biofuels via Hydrothermal Carbonization: a Review

Segundo A. Vásquez Llanos; Ada P. Barturén Quispe; Sebastian Huangal Scheineder; Isis C. Córdova Barrios; Juan T. Medina Collana; Marilín Sánchez Purihuamán; Pedro Córdova Mendoza; Carmen Carreño-Farfan; Felix M. Carbajal Gamarra

doi:10.3303/CET24110070

Energy Transformation: Assessment of Urban Lignocellulosic Biomass Biofuels via Hydrothermal Carbonization: a Review

Segundo A. Vásquez Llanos, Ada P. Barturén Quispe, Sebastian Huangal Scheineder, Isis C. Córdova Barrios, Juan T. Medina Collana, Marilín Sánchez Purihuamán, Pedro Córdova Mendoza, Carmen Carreño-Farfan, Felix M. Carbajal Gamarra

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

1 Scopus citations

Abstract

Urban lignocellulosic biomass (ULB), derived from the maintenance of public and private green spaces, such as parks, gardens, sports facilities, and areas along roads, emerges as a solid alternative to replace fossil sources. These resources stand out due to their abundance, low cost, and availability. Hydrothermal carbonization (HTC) emerged as an efficient technology to process this biomass that has a high moisture and ash content, eliminating the need for prior drying. This article reviews the conversion of ULB to solid biofuels through the HTC process, addressing the physicochemical and energetic properties of ULB and the resulting hydrochar, as well as the HTC process and the influence of the operating variables that affect the energetic quality of hydrochar. The carbonization temperature (180 to 280 °C) has a very significant influence more than the residence time (0.5 to 24 h) on the increase in the higher heating value (17.83 to 30.12 MJ kg^-1) and the fuel ratio, the decrease in the H/C and O/C ratios, the decrease in the combustibility index, the increase in the ignitability index (> 14.5 MJ kg^-1), and the carbon range. However, high carbonization temperatures and long residence times in the reactor are unsuitable because they require large amounts of energy to perform HTC. Therefore, biofuel prices, biomass logistics, optimization of HTC process variables, and reduction of energy consumption are challenges for the HTC process to generate a solid biofuel with excellent energy properties.

Original language	English
Pages (from-to)	415-420
Number of pages	6
Journal	Chemical Engineering Transactions
Volume	110
DOIs	https://doi.org/10.3303/CET24110070
State	Published - 2024

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Publisher Copyright:
© 2024, AIDIC Servizi S.r.l.

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Vásquez Llanos, S. A., Barturén Quispe, A. P., Scheineder, S. H., Córdova Barrios, I. C., Medina Collana, J. T., Purihuamán, M. S., Mendoza, P. C., Carreño-Farfan, C., & Carbajal Gamarra, F. M. (2024). Energy Transformation: Assessment of Urban Lignocellulosic Biomass Biofuels via Hydrothermal Carbonization: a Review. Chemical Engineering Transactions, 110, 415-420. https://doi.org/10.3303/CET24110070

@article{10f6a86cea4547aca19506e88e91fa83,

title = "Energy Transformation: Assessment of Urban Lignocellulosic Biomass Biofuels via Hydrothermal Carbonization: a Review",

abstract = "Urban lignocellulosic biomass (ULB), derived from the maintenance of public and private green spaces, such as parks, gardens, sports facilities, and areas along roads, emerges as a solid alternative to replace fossil sources. These resources stand out due to their abundance, low cost, and availability. Hydrothermal carbonization (HTC) emerged as an efficient technology to process this biomass that has a high moisture and ash content, eliminating the need for prior drying. This article reviews the conversion of ULB to solid biofuels through the HTC process, addressing the physicochemical and energetic properties of ULB and the resulting hydrochar, as well as the HTC process and the influence of the operating variables that affect the energetic quality of hydrochar. The carbonization temperature (180 to 280 °C) has a very significant influence more than the residence time (0.5 to 24 h) on the increase in the higher heating value (17.83 to 30.12 MJ kg-1) and the fuel ratio, the decrease in the H/C and O/C ratios, the decrease in the combustibility index, the increase in the ignitability index (> 14.5 MJ kg-1), and the carbon range. However, high carbonization temperatures and long residence times in the reactor are unsuitable because they require large amounts of energy to perform HTC. Therefore, biofuel prices, biomass logistics, optimization of HTC process variables, and reduction of energy consumption are challenges for the HTC process to generate a solid biofuel with excellent energy properties.",

author = "{V{\'a}squez Llanos}, {Segundo A.} and {Bartur{\'e}n Quispe}, {Ada P.} and Scheineder, {Sebastian Huangal} and {C{\'o}rdova Barrios}, {Isis C.} and {Medina Collana}, {Juan T.} and Purihuam{\'a}n, {Maril{\'i}n S{\'a}nchez} and Mendoza, {Pedro C{\'o}rdova} and Carmen Carre{\~n}o-Farfan and {Carbajal Gamarra}, {Felix M.}",

note = "Publisher Copyright: {\textcopyright} 2024, AIDIC Servizi S.r.l.",

year = "2024",

doi = "10.3303/CET24110070",

language = "English",

volume = "110",

pages = "415--420",

journal = "Chemical Engineering Transactions",

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Vásquez Llanos, SA , Barturén Quispe, AP, Scheineder, SH, Córdova Barrios, IC, Medina Collana, JT, Purihuamán, MS, Mendoza, PC, Carreño-Farfan, C & Carbajal Gamarra, FM 2024, 'Energy Transformation: Assessment of Urban Lignocellulosic Biomass Biofuels via Hydrothermal Carbonization: a Review', Chemical Engineering Transactions, vol. 110, pp. 415-420. https://doi.org/10.3303/CET24110070

TY - JOUR

T1 - Energy Transformation

T2 - Assessment of Urban Lignocellulosic Biomass Biofuels via Hydrothermal Carbonization: a Review

AU - Vásquez Llanos, Segundo A.

AU - Barturén Quispe, Ada P.

AU - Scheineder, Sebastian Huangal

AU - Córdova Barrios, Isis C.

AU - Medina Collana, Juan T.

AU - Purihuamán, Marilín Sánchez

AU - Mendoza, Pedro Córdova

AU - Carreño-Farfan, Carmen

AU - Carbajal Gamarra, Felix M.

PY - 2024

Y1 - 2024

N2 - Urban lignocellulosic biomass (ULB), derived from the maintenance of public and private green spaces, such as parks, gardens, sports facilities, and areas along roads, emerges as a solid alternative to replace fossil sources. These resources stand out due to their abundance, low cost, and availability. Hydrothermal carbonization (HTC) emerged as an efficient technology to process this biomass that has a high moisture and ash content, eliminating the need for prior drying. This article reviews the conversion of ULB to solid biofuels through the HTC process, addressing the physicochemical and energetic properties of ULB and the resulting hydrochar, as well as the HTC process and the influence of the operating variables that affect the energetic quality of hydrochar. The carbonization temperature (180 to 280 °C) has a very significant influence more than the residence time (0.5 to 24 h) on the increase in the higher heating value (17.83 to 30.12 MJ kg-1) and the fuel ratio, the decrease in the H/C and O/C ratios, the decrease in the combustibility index, the increase in the ignitability index (> 14.5 MJ kg-1), and the carbon range. However, high carbonization temperatures and long residence times in the reactor are unsuitable because they require large amounts of energy to perform HTC. Therefore, biofuel prices, biomass logistics, optimization of HTC process variables, and reduction of energy consumption are challenges for the HTC process to generate a solid biofuel with excellent energy properties.

AB - Urban lignocellulosic biomass (ULB), derived from the maintenance of public and private green spaces, such as parks, gardens, sports facilities, and areas along roads, emerges as a solid alternative to replace fossil sources. These resources stand out due to their abundance, low cost, and availability. Hydrothermal carbonization (HTC) emerged as an efficient technology to process this biomass that has a high moisture and ash content, eliminating the need for prior drying. This article reviews the conversion of ULB to solid biofuels through the HTC process, addressing the physicochemical and energetic properties of ULB and the resulting hydrochar, as well as the HTC process and the influence of the operating variables that affect the energetic quality of hydrochar. The carbonization temperature (180 to 280 °C) has a very significant influence more than the residence time (0.5 to 24 h) on the increase in the higher heating value (17.83 to 30.12 MJ kg-1) and the fuel ratio, the decrease in the H/C and O/C ratios, the decrease in the combustibility index, the increase in the ignitability index (> 14.5 MJ kg-1), and the carbon range. However, high carbonization temperatures and long residence times in the reactor are unsuitable because they require large amounts of energy to perform HTC. Therefore, biofuel prices, biomass logistics, optimization of HTC process variables, and reduction of energy consumption are challenges for the HTC process to generate a solid biofuel with excellent energy properties.

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U2 - 10.3303/CET24110070

DO - 10.3303/CET24110070

M3 - Review article

AN - SCOPUS:85202689974

SN - 2283-9216

VL - 110

SP - 415

EP - 420

JO - Chemical Engineering Transactions

JF - Chemical Engineering Transactions

ER -

Energy Transformation: Assessment of Urban Lignocellulosic Biomass Biofuels via Hydrothermal Carbonization: a Review

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