Miscanthus biomass quality composition and methods of feedstock preparation for conversion into synthetic diesel fuel

Kadžiulienė, Ž.; Jasinskas, Algirdas; Zinkevičius, Remigijus; Makarevičienė, Violeta; Šarūnaitė, Lina; Tilvikienė, Vita; Šlepetys, J.

doi:10.13080/z-a.2014.101.004

Cited by 9 publications

(13 citation statements)

References 26 publications

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“…using appropriate boilers, dry biomass fuels and complete combustion conditions, combined with cleaner biomass fuels producing limited emissions and exhibiting low toxicity is strongly recommended (Fachinger et al, 2017; Kaivosoja et al, 2013; Leskinen et al, 2014). Giant Miscanthus (Miscanthus x giganteus) is a high-yielding perennial grass with the potential to meet biomass fuel production criteria (Atkinson, 2009; Kadžiulienė et al, 2014). It is also economically viable and plays an important role in the sustainable production of renewable fuels and chemicals via thermo-chemical conversion (Sørensen et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

Cytotoxic and genotoxic responses of human lung cells to combustion smoke particles of Miscanthus straw, softwood and beech wood chips

Arif

Maschowski

Garra

et al. 2017

Atmospheric Environment

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Inhalation of particulate matter (PM) from residential biomass combustion is epidemiologically associated with cardiovascular and pulmonary diseases. This study investigates PM0.4–1 emissions from combustion of commercial Miscanthus straw (MS), softwood chips (SWC) and beech wood chips (BWC) in a domestic-scale boiler (40 kW). The PM0.4–1 emitted during combustion of the MS, SWC and BWC were characterized by ICP-MS/OES, XRD, SEM, TEM, and DLS. Cytotoxicity and genotoxicity in human alveolar epithelial A549 and human bronchial epithelial BEAS-2B cells were assessed by the WST-1 assay and the DNA-Alkaline Unwinding Assay (DAUA). PM0.4–1 uptake/translocation in cells was investigated with a new method developed using a confocal reflection microscope. SWC and BWC had a inherently higher residual water content than MS. The PM0.4–1 emitted during combustion of SWC and BWC exhibited higher levels of Polycyclic Aromatic Hydrocarbons (PAHs), a greater variety of mineral species and a higher heavy metal content than PM0.4–1 from MS combustion. Exposure to PM0.4–1 from combustion of SWC and BWC induced cytotoxic and genotoxic effects in human alveolar and bronchial cells, whereby the strongest effect was observed for BWC and was comparable to that caused by diesel PM (SRM 2 975), In contrast, PM0.4–1 from MS combustion did not induce cellular responses in the studied lung cells. A high PAH content in PM emissions seems to be a reliable chemical marker of both combustion efficiency and particle toxicity. Residual biomass water content strongly affects particulate emissions and their toxic potential. Therefore, to minimize the harmful effects of fine PM on health, improvement of combustion efficiency (aiming to reduce the presence of incomplete combustion products bound to PM) and application of fly ash capture technology, as well as use of novel biomass fuels like Miscanthus straw is recommended.

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Section: Introductionmentioning

confidence: 99%

Cytotoxic and genotoxic responses of human lung cells to combustion smoke particles of Miscanthus straw, softwood and beech wood chips

Arif

Maschowski

Garra

et al. 2017

Atmospheric Environment

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“…The maximum compression force of reed was the highest of all the plants under investigation and reached 549.2 N. The maximum compression force of bulrush pellets was 543.2 N and that of reed canary grass pellets reached only 324.2 N. Therefore, pellets made from these plants would be the least resistant to adverse effects during transportation, storage, or loading into a furnace of a boiler (Figure 1). Latvian scientists investigated the strength of 36 mm diameter cylindrical briquettes [43]. The density of their investigated briquettes was of 1135 kg m −3 dry matter (this density was similar to that of our tested pellets), and critical breaking pressure varied from 99 to 115 N mm −1 .…”

Section: Pellet Mechanical Strengthmentioning

confidence: 54%

“…where: w -pellet moisture content, %; a and b -coefficients of the equation. Latvian scientists investigated the strength of 36 mm diameter cylindrical briquettes [43]. The density of their investigated briquettes was of 1135 kg m −3 dry matter (this density was similar to that of our tested pellets), and critical breaking pressure varied from 99 to 115 N mm −1 .…”

Section: ƍ = a W + Bmentioning

confidence: 54%

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Energy Evaluation and Greenhouse Gas Emissions of Reed Plant Pelletizing and Utilization as Solid Biofuel

et al. 2020

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This paper presents the results of research on the preparation and use for energy purposes of three reed herbaceous energy plants: reed (Phragmites australis) and bulrush (Typha); both grown in local vicinities on lakes and riverbanks and reed canary grass (Phalaris arundinacea L.). The physical-mechanical characteristics (density, moisture, and ash content) of chopped and milled reeds were investigated. The investigation of mill fractional compositions determined the largest amount of mill—reed mill, collected on the sieves of 0.63 mm (40.0%). The pellet moisture ranged from 10.79% to 6.32%, while the density was 1178.9 kg m−3 for dry matter (DM) of reed. The ash content of reed, bulrush and reed canary grass pellets was 3.17%, 5.88%, and 7.99%, respectively. The ash melting temperature ranged from 865 to 1411 °C; these temperatures were high enough for ash melting. The determined pellet calorific value varied from 17.4 to 17.9 MJ kg−1 DM. The disintegration force, indicating pellet strength, ranged from 324.25 N for reed canary grass to 549.24 N for reed. The determined emissions of harmful pollutants—CO2, CO, NOx, and unburnt hydrocarbons (CxHy)—did not exceed the maximum permissible levels. The assessment of greenhouse gas emissions (GHG) from technology showed that the CO2 equivalents ranged from 7.3 to 10.1 kg CO2-eq. GJ−1 for reed and reed canary grass, respectively.

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“…After performed tests, research data will be processed by statistical -mathematical methods. Averages and their confidence intervals, estimated substantial difference in the threshold at 95 % probability are calculated during data processing time (Kadžiulienė et al, 2014).…”

Section: Methodsmentioning

confidence: 99%

Assessment of Herbal Plant Biofuel Pellet Quality Indicators

Jasinskas

Šarauskis

Gutautaitė

et al. 2015

Proceedings of the 7th International Scientific Conference Rural Development 2015

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Variety of vegetable raw materials is used for energetic needs: logging and wood processing waste, agricultural production byproducts: straws as well as specially cultivated trees, tall grass, rapeseeds, triticale and other herbaceous plants. In the performed scientific work, preparation and opportunities of use of energetic needs are estimated for non-conventional energy plants (elephant grass, orchard grass, common mugwort and fibrous nettle), technological parameters of processing these seeds and pressing into granules are explored, biometric and physic-mechanical properties of finished pellets are evaluated, and their resistance to impact forces is evaluate. Having examined humidity of pellets, it was found that maximum moisture content was in pellets of elephant grass and nettle -from 13.1 to 13.2%, while the smallest -in orchard grass pellets 10.0%. The largest density of non-conventional energetic pellet density was orchard -983.8 kg m -3 DM (dry matter) and common mugwort -926.7 kg m -3 DM, and density of elephant grass pellets was the lowest -619.3 kg m -3 DM. Results on resistance to deformability of non-conventional energetic crops granules indicate that the highest resistance against external forces is a pellet made of common mugwort: they decompose to 110.03 N force. Pellets of other plants disintegrate to smaller external force: fibrous nettle granules -to 90.6 N, orchard -to 67.3 N force. Elephant grass pellets have the smallest resistance to deformation and decompose more quickly (at 20 N). The research results show that pellets made of elephant grass are of the lowest quality; due to this, it is not recommended to use these plants in the form of pellets.

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Miscanthus biomass quality composition and methods of feedstock preparation for conversion into synthetic diesel fuel

Cited by 9 publications

References 26 publications

Cytotoxic and genotoxic responses of human lung cells to combustion smoke particles of Miscanthus straw, softwood and beech wood chips

Cytotoxic and genotoxic responses of human lung cells to combustion smoke particles of Miscanthus straw, softwood and beech wood chips

Energy Evaluation and Greenhouse Gas Emissions of Reed Plant Pelletizing and Utilization as Solid Biofuel

Assessment of Herbal Plant Biofuel Pellet Quality Indicators

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