Technical-environmental optimisation of the activated carbon production of an agroindustrial waste by means response surface and life cycle assessment

Sepúlveda-Cervantes, Cynthia V; Soto-Regalado, Eduardo; Rivas-García, Pasiano; Loredo‐Cancino, Margarita; Cerino-Córdova, Felipe dJ; Reyes, Refugio Bernardo García

doi:10.1177/0734242x17741680

Cited by 24 publications

(15 citation statements)

References 22 publications

(26 reference statements)

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“…Additionally, first-generation resources require large amounts of fertile land, and most agricultural land is already occupied. Therefore, a better fitting source for the production of biofuels is organic residues since they have no negative impact on food production or land use, resulting in a more sustainable feedstock utilization for the production of bioethanol [25][26][27][28].…”

Section: Introductionmentioning

confidence: 99%

Feasibility Assessment of a Bioethanol Plant in the Northern Netherlands

et al. 2019

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Due to the exhaustion and increased pressure regarding the environmental and political aspects of fossil fuels, the industrial focus has switched towards renewable energy resources. Lignocellulosic biowaste can come from several sources, such as industrial waste, agricultural waste, forestry waste, and bioenergy crops and processed into bioethanol via a biochemical pathway. Although much research has been done on the ethanol production from lignocellulosic biomass, the economic viability of a bioethanol plant in the Northern Netherlands is yet unknown, and therefore, examined. In this thesis, the feasibility study of a bioethanol plant treating sugar beet pulp, cow manure, and grass straw is conducted using the simulation software SuperPro Designer. Results show that it is not economically viable to treat the tested lignocellulosic biomass for the production of bioethanol, since all three original cases result in a negative net present value (NPV). An alternative would be to exclude the pretreatment step from the process. Although this results in a lower production of bioethanol per year, the plant treating sugar beet pulp (SBP) and grass straw (GS) becomes economically viable since the costs have significantly decreased.

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Section: Introductionmentioning

confidence: 99%

Feasibility Assessment of a Bioethanol Plant in the Northern Netherlands

et al. 2019

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“…Por el contrario, Dominguez Mendoza [16] reporta un rendimiento del 32 % al carbonizar bagazo de agave, pero obtiene un hydrochar con área superficial de 306 m?/g, similar incluso a algunos carbones activados producidos a partir de biomasas. Si bien el presente trabajo tuvo como principal objetivo verificar la viabilidad de la producción de hydrochar a partir de nejayote, es recomendable tomar en cuenta como variable de respuesta no solamente el rendimiento, sino también alguna otra variable indicativa de la calidad del producto o incluso de la sustentabilidad de este, tal y como lo han hecho otros autores [6,8,[17][18][19].…”

Section: Resultados Y Discusiónunclassified

Carbonización hidrotermal del nejayote de maíz

et al. 2021

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Los residuos líquidos del proceso de nixtamalización (nejayote) representan un problema ambiental debido a sus característicasfisicoquímicas y la disposición inadecuada de estos residuos por parte de algunos molinos. En esta investigación se propone el método de carbonización hidrotermal para el aprovechamiento del nejayote, ya que este método permite trabajar con biomasas que presenten un gran contenido de humedad. El nejayote fue obtenido en condiciones de laboratorio y se introdujo en un reactor hidrotermal con capacidad de 100 mL bajo las condiciones establecidas por un diseño de experimentos central compuesto. Una vez separados los productos resultantes (líquido y sólido), se secó la muestra sólida y se calcularon rendimientos. Posteriormente se buscaron las condiciones experimentales que maximizaran el rendimiento, encontrando el punto óptimo a una temperatura de carbonización de 200 Celsius, pH de 3.3 y un tiempo en el rango de 12 a 24 horas; a estas condiciones se predice un rendimiento de 30 % con una deseabilidad de 0.919.

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“…Previous studies indicate that energy consumptions and greenhouse gas (GHG) emissions are mainly driven by the AC production stage that usually has large variations due to differences in the types and composition of biomass, process operational conditions, and sources of energy. , A few studies have tried to explore such variations by investigating AC production scenarios by varying process parameters. For example, Sepúlveda-Cervantes et al conducted a gate-to-gate LCA of soybean shell-based AC production using zinc chloride activation . By varying the operational conditions (i.e., activation temperature, time, and impregnation ratio), the electricity consumption of AC production changed from 17 to 50 MJ/kg AC, and the GHG emissions varied between 5.86 to 47.2 kg CO 2 -eq/kg AC .…”

Section: Introductionmentioning

confidence: 99%

“…For example, Sepúlveda-Cervantes et al conducted a gate-to-gate LCA of soybean shell-based AC production using zinc chloride activation . By varying the operational conditions (i.e., activation temperature, time, and impregnation ratio), the electricity consumption of AC production changed from 17 to 50 MJ/kg AC, and the GHG emissions varied between 5.86 to 47.2 kg CO 2 -eq/kg AC . Arena et al analyzed the impacts of different energy sources on the environmental footprints of coconut shell AC, which showed a significant reduction of most environmental impact categories (60–80%) by using electricity from renewable sources .…”

Section: Introductionmentioning

confidence: 99%

Generating Energy and Greenhouse Gas Inventory Data of Activated Carbon Production Using Machine Learning and Kinetic Based Process Simulation

Ming-yang

Kelley

Yao

2019

ACS Sustainable Chem. Eng.

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Understanding the environmental implications of activated carbon (AC) produced from diverse biomass feedstocks is critical for biomass screening and process optimization for sustainability. Many studies have developed Life Cycle Assessment (LCA) for biomass-derived AC. However, most of them either focused on individual biomass species with differing process conditions or compared multiple biomass feedstocks without investigating the impacts of feedstocks and process variations. Developing LCA for AC from diverse biomass is time-consuming and challenging due to the lack of process data (e.g., energy and mass balance). This study addresses these knowledge gaps by developing a modeling framework that integrates artificial neural network (ANN), a machine learning approach, and kinetic-based process simulation. The integrated framework is able to generate Life Cycle Inventory data of AC produced from 73 different types of woody biomass with 250 characterization data samples. The results show large variations in energy consumption and GHG emissions across different biomass species (43.4–277 MJ/kg AC and 3.96–22.0 kg CO2-eq/kg AC). The sensitivity analysis indicates that biomass composition (e.g., hydrogen and oxygen content) and process operational conditions (e.g., activation temperature) have large impacts on energy consumption and GHG emissions associated with AC production.

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Technical-environmental optimisation of the activated carbon production of an agroindustrial waste by means response surface and life cycle assessment

Cited by 24 publications

References 22 publications

Feasibility Assessment of a Bioethanol Plant in the Northern Netherlands

Feasibility Assessment of a Bioethanol Plant in the Northern Netherlands

Carbonización hidrotermal del nejayote de maíz

Generating Energy and Greenhouse Gas Inventory Data of Activated Carbon Production Using Machine Learning and Kinetic Based Process Simulation

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