Analysis of the Effect of the Biomass Torrefaction Process on Selected Parameters of Dust Explosivity

Bajcar, Marcin; Saletnik, Bogdan; Zaguła, Grzegorz; Puchalski, Czesław

doi:10.3390/molecules25153525

Cited by 6 publications

(9 citation statements)

References 38 publications

(39 reference statements)

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“…Pyrolysis leads to higher carbon concentrations and volatile contents and results in the increased brittleness of the thermally processed products. A similar relationship was reported by Bajcar et al (2020), who assessed the dust explosivity in the raw biomass of wheat straw and energy willow and in products of the torrefaction process applied to those materials. The authors observed that Pmax increased by a maximum of 28% with a higher torrefaction process temperature [47].…”

Section: Discussionsupporting

confidence: 77%

“…A similar relationship was reported by Bajcar et al (2020), who assessed the dust explosivity in the raw biomass of wheat straw and energy willow and in products of the torrefaction process applied to those materials. The authors observed that Pmax increased by a maximum of 28% with a higher torrefaction process temperature [47]. Półka (2020) reported a maximum explosion pressure for coke dust amounting to 6.84 bar.…”

Section: Discussionsupporting

confidence: 77%

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Effect of the Pyrolysis Process Applied to Waste Branches Biomass from Fruit Trees on the Calorific Value of the Biochar and Dust Explosivity

et al. 2021

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The article discusses the findings related to the calorific value as well as the explosion and combustion parameters of dust from the raw biomass of fruit trees, i.e., apple, cherry, and pear branches, and from biochars produced using this type of biomass during pyrolysis processes conducted under various conditions. The plant biomass was thermally processed at 400, 450, or 500 °C for a duration of 5, 10, or 15 min. The study aimed to identify the calorific value of the biomass obtained from waste produced in orchards and to estimate the explosion hazard during the processing of such materials and during the storage of the resulting solid fuels. Tests were conducted to assess the total contents of carbon, ash, nitrogen, hydrogen, and volatile substances as well as the calorific value. The findings show a significant effect of the thermal transformation of fruit tree branches on the calorific value of the biochars that were produced. It was found that the mean calorific value of all of the biochars was increased by 62.24% compared to the non-processed biomass. More specifically, the mean calorific values of the biochars produced from apple, cherry, and pear branches amounted to 27.90, 28.75, and 26.84 MJ kg−1, respectively. The maximum explosion pressure Pmax measured for the dust from the biomass and for the biochars was in the range 7.56–7.8 and 7.95–11.72 bar, respectively. The maximum rate of pressure rose over time (dp/dt)max in the case of the dust from the biomass, which was in the range of 274.77–284.97 bar s−1, and the dust from biochar amounted to 282.05–353.41 bar s−1. The explosion index Kst max measured for non-processed biomass and biochars was found to range from 74.46 to 77.23 and from 76.447 to 95.77 bar s−1, respectively. It was also shown that a change in the temperature and duration of the pyrolysis process affected the quality of the biochars that were obtained. The findings show that pyrolysis, as a method of plant biomass processing, positively affects the calorific value of the products and does not lead to an increased risk of explosion during the treatment and storage of such materials. It is necessary, however, to continue research on biomass processing in order to develop practices that adequately ensure safety during the production of novel fuels.

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Section: Discussionsupporting

confidence: 77%

Section: Discussionsupporting

confidence: 77%

Effect of the Pyrolysis Process Applied to Waste Branches Biomass from Fruit Trees on the Calorific Value of the Biochar and Dust Explosivity

et al. 2021

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“…Bajcar et al showed an increase in the explosion index K st max , which, in the case of raw willow biomass, was estimated at the level of 72 bar s −1 , and for the torrefied material amounted to 81 bar s −1 . A similar tendency was identified in the case of wheat straw; the dust explosion index K st max of raw biomass amounted to 55 bar s −1 , and with the torrefied materials it increased to 62 bar s −1 [ 143 ]. Saletnik et al classified the thermally unprocessed oak, coniferous pellets and their mixture, as well as the thermally processed forms obtained from them, into the first class of dust explosion hazard (St1)—a material not susceptible to explosiveness.…”

Section: Resultssupporting

confidence: 66%

“…The thermal processes leads to an increased concentration of carbon, higher contents of volatile substances, and greater brittleness observed in the materials after thermal treatment. Despite the visible trend, these differences are not significant and do not result in a change of dust classification [ 143 ]. According to Cashdollar, Cordero et al and Demirbas, as well as other researchers, the differences between raw and thermally processed biomass can mainly be explained by the different emissivity of the respective materials linked to the mechanisms of heat transfer [ 145 , 146 , 147 ].…”

Section: Resultsmentioning

confidence: 99%

Oak Biomass in the Form of Wood, Bark, Brushwood, Leaves and Acorns in the Production Process of Multifunctional Biochar

Saletnik

Zaguła

et al. 2022

Molecules

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Biochar from forest biomass and its remains has become an essential material for environmental engineering, and is used in the environment to restore or improve soil function and its fertility, where it changes the chemical, physical and biological processes. The article presents the research results on the opportunity to use the pyrolysis process to receive multifunctional biochar materials from oak biomass. It was found that biochars obtained from oak biomass at 450 and 500 °C for 10 min were rich in macronutrients. The greatest variety of the examined elements was characterized by oak-leaf pyrolysate, and high levels of Ca, Fe, K, Mg, P, S, Na were noticed. Pyrolysates from acorns were high in Fe, K, P and S. Oak bark biochars were rich in Ca, Fe, S and contained nitrogen. In addition, biomass pyrolysis has been found to improve energy parameters and does not increase the dust explosion hazard class. The oak biomass pyrolytic at 450 and 500 °C after 10 min increases its caloric content for all samples tested by at least 50%. The highest caloric value among the raw biomass tested was observed in oak bark: 19.93 MJ kg−1 and oak branches: 19.23 MJ kg−1. The mean and highest recorded Kst max were 94.75 and 94.85 bar s−1, respectively. It can be concluded that pyrolysis has the potential to add value to regionally available oak biomass. The results described in this work provide a basis for subsequent, detailed research to obtain desired knowledge about the selection of the composition, purpose, and safety rules of production, storage, transport and use of biochar materials.

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“…During the production of wood chips, wood dust often swirls in cloud concentrations, which, especially in combination with fuel vapors and engine heat, can create a dangerous explosive mixture that can endanger the life and health of workers, as well as cause damage to property and equipment [90,91].…”

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confidence: 99%

Overview of Health and Safety Risks in the Process of Production and Storage of Forest Biomass for Energy Purposes—A Review

Gejdoš,

Lieskovský

2024

Energies

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With increasing demands on the quality and quantity of produced biomass, as the main element of the knowledge-based economy, people and the issue of safety and health protection at work are coming to the fore. The aim of the work is the synthesis and overview of the results of the analysis of the health and safety risks of the production of forest biomass in various production phases, starting with its cultivation, through the harvesting production and transport process, up to the issue of its safe storage until it is used for the production of primary energy. Based on the analyzed overview of the existing risks in the production and storage of biomass, it can be concluded that the largest number of works is dedicated to the technological process of storage and consumption of the produced forms of biomass. Of the risks in this phase, the largest number of works is devoted to the risks of the production of spores of phytopathogens and fungi threatening human health. Further research should be primarily oriented toward creating models and modeling the processes of the emergence of these risk factors and the dynamics of their growth.

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Analysis of the Effect of the Biomass Torrefaction Process on Selected Parameters of Dust Explosivity

Cited by 6 publications

References 38 publications

Effect of the Pyrolysis Process Applied to Waste Branches Biomass from Fruit Trees on the Calorific Value of the Biochar and Dust Explosivity

Effect of the Pyrolysis Process Applied to Waste Branches Biomass from Fruit Trees on the Calorific Value of the Biochar and Dust Explosivity

Oak Biomass in the Form of Wood, Bark, Brushwood, Leaves and Acorns in the Production Process of Multifunctional Biochar

Overview of Health and Safety Risks in the Process of Production and Storage of Forest Biomass for Energy Purposes—A Review

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