3D Eulerian-Eulerian modeling of a screw reactor for biomass thermochemical conversion. Part 2: Slow pyrolysis for char production

The effect of pressure on the thermochemical conversion of woody biomass and lignin in the presence of carbonate additives has been investigated at moderate temperatures (600 and 800°C). A ternary...

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Analytical Investigations of Kinetic and Heat Transfer in Slow Pyrolysis of a Biomass Particle

International Journal of Renewable Energy Development ◽

10.14710/ijred.2.2.105-115 ◽

2013 ◽

Vol 2 (2) ◽

pp. 105-115

Author(s):

S.J Ojolo ◽

C.A. Osheku ◽

M.G Sobamowo

Keyword(s):

Heat Transfer ◽

Analytical Solutions ◽

Experimental Results ◽

Analytical Models ◽

Thermochemical Conversion ◽

Percentage Error ◽

Slow Pyrolysis ◽

Average Percentage ◽

Transfer Equations ◽

Standard Deviations

The utilization of biomass for heat and power generation has aroused the interest of most researchers especially those of energy .In converting solid fuel to a usable form of energy,pyrolysis plays an integral role. Understanding this very important phenomenon in the thermochemical conversion processes and representing it with appropriate mathematical models is vital in the design of pyrolysis reactors and biomass gasifiers. Therefore, this study presents analytical solutions to the kinetic and the heat transfer equations that describe the slow pyrolysis of a biomass particle. The effects of Biot number, temperature and residence time on biomass particle decomposition were studied. The results from the proposed analytical models are in good agreement with the reported experimental results. The developed analytical solutions to the heat transfer equations which have been stated to be “analytically involved” showed average percentageerror and standard deviations 0.439 and 0.103 from the experimental results respectively as compared with previous model in literature which gives average percentage error and standard deviations 0.75 and 0.106 from the experimental results respectively. This work is of great importance in the design of some pyrolysis reactors/units and in the optimal design of the biomass gasifiers.

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Miscanthus to Biocarbon for Canadian Iron and Steel Industries: An Innovative Approach

Energies ◽

10.3390/en14154493 ◽

2021 ◽

Vol 14 (15) ◽

pp. 4493

Author(s):

Trishan Deb Abhi ◽

Omid Norouzi ◽

Kevin Macdermid-Watts ◽

Mohammad Heidari ◽

Syeda Tasnim ◽

...

Keyword(s):

Carbon Content ◽

Ghg Emissions ◽

Hydrothermal Carbonization ◽

Ash Content ◽

Innovative Approach ◽

Thermochemical Conversion ◽

Partial Substitution ◽

Iron And Steel ◽

Slow Pyrolysis ◽

Ironmaking Process

Iron-based industries are one of the main contributors to greenhouse gas (GHG) emissions. Partial substitution of fossil carbon with renewable biocarbon (biomass) into the blast furnace (BF) process can be a sustainable approach to mitigating GHG emissions from the ironmaking process. However, the main barriers of using biomass for this purpose are the inherent high alkaline and phosphorous contents in ash, resulting in fouling, slagging, and scaling on the BF surface. Furthermore, the carbon content of the biomass is considerably lower than coal. To address these barriers, this research proposed an innovative approach of combining two thermochemical conversion methods, namely hydrothermal carbonization (HTC) and slow pyrolysis, for converting biomass into suitable biocarbon for the ironmaking process. Miscanthus, which is one of the most abundant herbaceous biomass sources, was first treated by HTC to obtain the lowest possible ash content mainly due to reduction in alkali matter and phosphorous contents, and then subjected to slow pyrolysis to increase the carbon content. Design expert 11 was used to plan the number of the required experiments and to find the optimal condition for HTC and pyrolysis steps. It was found that the biocarbon obtained from HTC at 199 °C for 28 min and consecutively pyrolyzed at 400 °C for 30 min showed similar properties to pulverized coal injection (PCI) which is currently used in BFs due to its low ash content (0.19%) and high carbon content (79.67%).

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Acaricidal Properties of Bio-Oil Derived From Slow Pyrolysis of Crambe abyssinica Fruit Against the Cattle Tick Rhipicephalus microplus (Acari: Ixodidae)

Frontiers in Physiology ◽

10.3389/fphys.2021.768522 ◽

2021 ◽

Vol 12 ◽

Author(s):

Camila Mattos ◽

Juliana Andrade ◽

Bruno Salarini Peixoto ◽

Nayara Luiza Tavares Moraes ◽

Marcia Cristina da Cunha Veloso ◽

...

Keyword(s):

Chemical Composition ◽

Gonadosomatic Index ◽

Rhipicephalus Microplus ◽

Egg Laying ◽

Gas Chromatography Mass Spectrometry ◽

Thermochemical Conversion ◽

Cattle Tick ◽

Crambe Abyssinica ◽

Slow Pyrolysis ◽

Bio Oil

Slow pyrolysis is a process for the thermochemical conversion of biomasses into bio-oils that may contain a rich chemical composition with biotechnological potential. Bio-oil produced from crambe fruits was investigated as to their acaricidal effect. Slow pyrolysis of crambe fruits was performed in a batch reactor at 400°C and chemical composition was analyzed by gas chromatography-mass spectrometry (GC-MS). The bio-oil collected was used in bioassays with larvae and engorged females of the cattle tick Rhipicephalus microplus. Biological assays were performed using the larval packet test (LPT) and adult immersion test. The GC-MS of crambe fruit bio-oil revealed mainly hydrocarbons such as alkanes and alkenes, phenols, and aldehydes. The bio-oil in the LPT exhibited an LC90 of 14.4%. In addition, crambe bio-oil caused female mortality of 91.1% at a concentration of 15% and a high egg-laying inhibition. After ovary dissection of treated females, a significant reduction in gonadosomatic index was observed, indicating that bio-oil interfered in tick oogenesis. Considering these results, it may be concluded that slow pyrolysis of crambe fruit affords a sustainable and eco-friendly product for the control of cattle tick R. microplus.

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Thermochemical conversion of raw and defatted algal biomass via hydrothermal liquefaction and slow pyrolysis

Bioresource Technology ◽

10.1016/j.biortech.2012.01.008 ◽

2012 ◽

Vol 109 ◽

pp. 178-187 ◽

Cited By ~ 268

Author(s):

Derek R. Vardon ◽

Brajendra K. Sharma ◽

Grant V. Blazina ◽

Kishore Rajagopalan ◽

Timothy J. Strathmann

Keyword(s):

Algal Biomass ◽

Hydrothermal Liquefaction ◽

Thermochemical Conversion ◽

Slow Pyrolysis

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Integration of two-stage thermochemical treatment and chemical leaching for extraction of advanced biochar and high value critical raw materials from sewage sludge

E3S Web of Conferences ◽

10.1051/e3sconf/202123801008 ◽

2021 ◽

Vol 238 ◽

pp. 01008

Author(s):

Andre Salimbeni ◽

Andrea Maria Rizzo ◽

David Chiaramonti

Keyword(s):

Acid Leaching ◽

Thermochemical Treatment ◽

Calorific Value ◽

Ash Content ◽

Thermochemical Conversion ◽

Second Phase ◽

High Concentration ◽

Chemical Leaching ◽

Slow Pyrolysis ◽

Thermal Coal

The proposed study aims at assessing the reliability of a new sludge conversion technology, based on integrating thermochemical treatment, with a chemical leaching stage for producing high quality biochar and valuable liquid with high concentration of phosphorus and other critical elements. The concept is based on the fact that sludge ash usually contains about 25% of CaO, 20% of P2O5, and about 25-30% of SiO2. With the removal of these elements, ash content is drastically reduced. The study is thus composed of two phases: (1) assessment of sludge thermochemical conversion routes, and (2) chemical leaching produced biochar. In the first phase, three thermochemical routes are investigated: HTC of fresh sludge at 80% moisture, slow pyrolysis of dry sludge, slow pyrolysis of HTC solid (hydrochar). In the second phase, the solid obtained by slow pyrolysis (biochar) is upgraded through leaching treatment to extract inorganic valuable elements: P, Mg, K. The first phase of the study demonstrated that processing dry sludge in slow pyrolysis at 450°C allows to obtain a low volatile carbonaceous product with characteristics similar to a thermal coal. Second phase demonstrated that, after acid leaching process using HNO3, ash content in biochar decreased from 41.63% to 16.67%. This method also demonstrated to be a valid solution to extract more than 90% of P, K, and Mg contained in the solid, making these elements available for being recycled in agriculture and other industrial uses. At the same time, the increase of the biochar C content and calorific value makes it a valid substitute of fossil coals.

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