Your search keyword '"Sermyagina E"' showing total 7 results

1. Study on properties related to energy recovery from waste streams in Finland

Author

Sermyagina, E., primary, Nikku, M., additional, Vakkilainen, E., additional, and Hyppänen, T., additional

Published

2017

2. Effect of hydrothermal carbonization and torrefaction on spent coffee grounds

Author

Sermyagina, E., Mendoza, C., and Deviatkin, I.

Subjects

biomass pretreatment, hydrothermal carbonization, spent coffee grounds, torrefaction, articles, article

Abstract

Received: February 1st, 2021 ; Accepted: March 28th, 2021 ; Published: April 6th, 2021 ; Correspondence: ekaterina.sermyagina@lut.fi Coffee is one of the most tradable commodities worldwide with the current global consumption of over 10 billion kilograms of coffee beans annually. At the same time, a significant amount of solid residues, which are known as spent coffee grounds (SCG), is generated during instant coffee manufacturing and coffee brewing. Those residues have a high potential in various applications, yet they remain mostly unutilized. The current work presents the experimental comparison of two pretreatment technologies - hydrothermal carbonization (HTC) and torrefaction - for converting SCG into a valuable char. The results showed that low-temperature torrefaction (< 250 °C) has a negligible effect on feedstock properties due to initial pre-processing of coffee beans. However, the energy conversion efficiency of torrefaction at higher temperatures is comparable with that of HTC. The average energy yields for high-temperature torrefaction (> 250 °C) and HTC were on the level of 88%. Devolatilization and depolymerization reactions reduce oxygen and increase carbon contents during both processes: chars after torrefaction at 300 °C and HTC at 240 °C had 23–28% more carbon and 43–46% less oxygen than the feedstock. Both pretreatment methods led to a comparable increase in energy density: the highest HHV of 31.03 MJ kg-1 for torrefaction at 300 °C and 32.33 MJ kg-1 for HTC at 240 °C, which is similar to HHV of anthracite. The results showed that both processes can be effectively used to convert SCG into energy-dense char, even though HTC led to slightly higher energy densification rates.

Published

2021

3. Use of principal component analysis to evaluate thermal properties and combustibility of coffee-pine wood briquettes

Author

Mendoza Martinez, C.L., Sermyagina, E., Silva de Jesus, M., and Vakkilainen, E.

Subjects

reactivity, solid biofuels, combustion rate, articles, article, briquette, chemometrics

Abstract

Submitted: February 1st, 2021 ; Accepted: March 30th, 2021 ; Published: May 21st, 2021 ; Correspondence: clara.mendoza.martinez@lut.fi The coffee production chain is a potential source of residual biomass inherent to the high productivity that can contribute to the generation of value-added products. The residues from the coffee sector are typically disposed to landfill without treatment causing potential environmental inconveniences. Briquetting presents an alternative process to produce a uniform fuel with high energy density. Briquettes facilitates easy transportation, enables better handling and storage of biomass residues. Properties such as low equilibrium moisture content, high energy density and compressive strength were reported for different coffee-pine wood briquettes treatments. Moreover, understanding of the thermal properties of the briquettes during combustion is crucial to evaluate their final application. This research is the first study that investigates the combustibility properties and kinetic parameters of the thermal decomposition of briquettes from coffee-pine wood using differential and integral thermal analysis under non-isothermal conditions. Multivariate analysis of the collected parameters through principal components analysis (PCA), was implemented to reduce the dimensionality of the data. The desired profile in the combustibility is directly related to high temperatures and long burning times, thus, the tested briquettes displayed a significant combustibility potential, reporting peak temperatures and burnout times around 600 °C and 27 minutes, respectively. Activation energy kinetic parameter in the range of 12–42 kJ mol-1 and average reactivity of 0.14–0.22 min-1 , were also found. The results revealed the not thermally hard material to degrade when compared to biomasses typically used for combustion.

Published

2021

4. Conversion of cellulose to activated carbons for high-performance supercapacitors

Author

Sermyagina, E., Murashko, K., Nevstrueva, D., Pihlajamäki, A., and Vakkilainen, E.

Subjects

hydrothermal carbonization, supercapacitors, articles, article, activated carbon, cellulose, electrodes

Abstract

Biomass-derived activated carbons are promising materials that can be used in various applications. Current work investigates the possibilities of the cellulose-derived activated carbons in substituting the commercial alternatives for the supercapacitors’ electrodes with high efficiency, stable performance and relatively low cost. Hydrothermal carbonization (HTC) followed by chemical activation with KOH is used to convert cellulose into highly porous activated carbons. The effect of HTC parameters on the material porosity development and electrochemical properties of the electrodes is evaluated with several variations of the residence time and the weight ratio between cellulose and water during the pretreatment. The analysis shows that intensification of the HTC process (longer residence time and higher water/cellulose ratio) results in increase of the surface area of both hydrochar samples and subsequent activated carbons: with the highest surface area for the sample produced after 2 h HTC treatment with water/cellulose ratio of 6/1 – 2,645 m2 g -1 . As for the electrochemical analysis, the highest values of the specific capacitance are found for the samples produced from 2 h HTC treatment: 110.3 F g -1 (water/cellulose ratio of 3/1) and 102.5 F g -1 (water/cellulose ratio of 6/1). Additionally, it is noted that electrodes produced from the samples treated during 4 h have higher impedance at low operation frequency. The present study proves the possibility to substitute commercial activated carbons with cellulose-derived materials, the porosity of which can be tuned accordingly already during the pretreatment step.

Published

2020

5. Use of principal component analysis to evaluate thermal properties and combustibility of coffee-pine wood briquettes.

Author

Mendoza Martinez, C. L., Sermyagina, E., Silva de Jesus, M., and Vakkilainen, E.

Subjects

BRIQUETS, PRINCIPAL components analysis, THERMAL analysis, DIFFERENTIAL thermal analysis, HARD materials, THERMAL properties

Abstract

The coffee production chain is a potential source of residual biomass inherent to the high productivity that can contribute to the generation of value-added products. The residues from the coffee sector are typically disposed to landfill without treatment causing potential environmental inconveniences. Briquetting presents an alternative process to produce a uniform fuel with high energy density. Briquettes facilitates easy transportation, enables better handling and storage of biomass residues. Properties such as low equilibrium moisture content, high energy density and compressive strength were reported for different coffee-pine wood briquettes treatments. Moreover, understanding of the thermal properties of the briquettes during combustion is crucial to evaluate their final application. This research is the first study that investigates the combustibility properties and kinetic parameters of the thermal decomposition of briquettes from coffee-pine wood using differential and integral thermal analysis under non-isothermal conditions. Multivariate analysis of the collected parameters through principal components analysis (PCA), was implemented to reduce the dimensionality of the data. The desired profile in the combustibility is directly related to high temperatures and long burning times, thus, the tested briquettes displayed a significant combustibility potential, reporting peak temperatures and burnout times around 600 °C and 27 minutes, respectively. Activation energy kinetic parameter in the range of 12-42 kJ mol-1 and average reactivity of 0.14-0.22 min-1, were also found. The results revealed the not thermally hard material to degrade when compared to biomasses typically used for combustion. [ABSTRACT FROM AUTHOR]

Published

2021

6. An Analysis of Brazilian Biomass Focusing on Thermal Conversion for Energy Production: A Partnership between Brazilian and Finnish Universities

Author

Alves Rocha, E.P., Borges Gomes, F.J., Sermyagina, E., Cardoso, M., Vakkilainen, E., and Colodette, J.L.

Subjects

Biomass

Abstract

Renewable energy (mainly hydroelectric power plants) has a significant share in energy generation sector in Brazil. Recent climate changes, however, resulted in lower rainfall indexes and acted as a driving factor for the increasing interest in biomass applications. Therefore, having the land available for forest planting and a critical need for a new source of renewable energy, Brazil has the potential to further increase the energy generation from biomass. Due to the diverse nature of biomass materials, their properties range widely and exhibit different behaviors in thermal processes. To choose the most efficient way for production of energy, it is required to know the energy potential of the biomass samples. This study focuses on the physical-chemical characterization of nine lignocellulosic biomasses widely available in Brazil: five types of eucalyptus wood chips, sugarcane bagasse, elephant grass, bamboo, and coconut husk. Some characteristics regarded as important to thermochemical conversion are evaluated, such as: biomass chemical composition - polisacharides (glucans, xylans, galactans, mannans, arabinans), total uronic acids, acetyl groups, lignin, chloride, elementary analysis of the ash (Cu, Fe, Ca, Mn, Mg and K), silica and extractives, heating value, ultimate and proximate analyses. Moreover, the studied samples were investigated by thermogravimetric analysis (TG and DTG). The evaluation of these characteristics is important for understanding the processes of the thermochemical conversion of biomasses., Proceedings of the 23rd European Biomass Conference and Exhibition, 1-4 June 2015, Vienna, Austria, pp. 294-298

Published

2015

7. Life cycle assessment of alternative pulp mill sludge treatment methods in Finland.

Author

Salcedo-Puerto O, Breton M, Sermyagina E, Gonçalves L, Cardoso M, Havukainen J, Vakkilainen E, and Mendoza-Martinez C

Subjects

Finland, Waste Disposal, Fluid methods, Composting methods, Paper, Sewage, Incineration methods, Industrial Waste analysis

Abstract

Proper management of wastewater treatment plant side streams in pulp and paper mills is a matter of great interest. This study evaluates the environmental impact of different strategies in the management of biosludge from pulp and paper mills in Finland through a Life Cycle Assessment methodology. The base industrial standard practice, biosludge incineration for energy recovery and ash landfill disposal (Scenario 1), was compared to the alternative process of hydrothermal carbonization. The hydrochar generated from hydrothermal carbonization was evaluated for energy recovery through incineration (Scenario 2), or for use in composting for nutrient recovery (Scenario 3). The results showed that the hydrothermal process improved the overall environmental performance of the sludge management, particularly in terms of energy consumption and greenhouse gas emissions. The use of hydrochar as a soil amendment in composting also resulted in a significant reduction on the environmental impact compared to the other two scenarios. Overall, this study highlights the potential of hydrothermal carbonization and hydrochar utilization as sustainable options for managing biosludge from pulp mills., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2024