Detailed kinetic analysis of oil shale pyrolysis TGA data

Tiwari, Pankaj; Deo, Milind

doi:10.1002/aic.12589

Cited by 89 publications

(63 citation statements)

References 62 publications

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“…1b). The first weight-loss region around $250-500°C is dominated by the desired pyrolysis of kerogen [31]. The second weight-loss region located above 650°C is dominated mainly by the decomposition of carbonates such as calcite in the [31,18].…”

Section: Methodsmentioning

confidence: 98%

“…Note: the Q Ads value for OS ash is the value for the ash prepared by per gram of raw OS, and thus the unit (J g À1 K À1 ) of the Q Ads for OS ash in the figure is also joules per gram of raw OS per Kelvin. non-isothermal mode, the decomposition of kerogen could be represented by the following reaction [31]:…”

Section: Reaction Kinetics Of Kerogen Decomposition In Different Procmentioning

confidence: 99%

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Identifying the reaction mechanism of oil-shale self-heating retorting by thermal analysis techniques

Guo

Pei

Wang

et al. 2015

Fuel

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Section: Methodsmentioning

confidence: 98%

Section: Reaction Kinetics Of Kerogen Decomposition In Different Procmentioning

confidence: 99%

Identifying the reaction mechanism of oil-shale self-heating retorting by thermal analysis techniques

Guo

Pei

Wang

et al. 2015

Fuel

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“…Capillary gases may be oxidizing, inert, or reducing. An oxidizing atmosphere, such as air or oxygen, combusts organic materials and oxidizes metals . Changing oxidation states complicates the analysis as the mass increases.…”

Section: Introductionmentioning

confidence: 99%

Experimental methods in chemical engineering: Thermogravimetric analysis—TGA

et al. 2019

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Thermogravimetric analysis (TGA) is a quantitative analytical technique that monitors the mass of a sample from 1 mg to several g as a furnace ramps temperature to as high as 1600°C under a stable or changing gas flow. The first gravimetric test was in 27 BC when Vitruvius measured limestone's change of mass as it calcined to lime. In modern chemical engineering, researchers apply the technique to derive conversions, kinetics, and mechanisms for any process with a change of mass by isothermal, non‐isothermal, and quasi‐isothermal methods. The mass drops as the sample decomposes, volatile compounds evaporate, or the oxidation state decreases, while in reactive environments (with O2, for example), the mass of transition metals may increase. TGA is incapable of detecting phase transitions, polymorphic transformations, or reactions for which mass is invariant. DSC or DTA couple with TGA to help deconvolute a DSC plot by separating physical changes from chemical changes. Evolved gas analysis techniques monitor the gaseous products exiting the TGA furnace on‐line as the temperature ramps. A bibliometric map of keywords from articles citing TGA indexed by Web of Science in 2016 and 2017 identified five research clusters: nanoparticles, performance, and films; crystal structures, acid, and oxidation; composites, nanocomposites, and mechanical properties; kinetics, pyrolysis, and temperature; and adsorption, water and wastewater, and aqueous solutions. This review provides an overview of the basic principles of modern TGA.

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“…Moreover, heating rate is a significant factor and should not be more than 10.0 or 20.0°C/min to get a stable and informative TG plot . On the other hand, the flow rate of nitrogen gas was set at 50 mL/min which is often recommended for oil shale . As indicated in Figure , typical TG plots were reported which confirmed that serious composition of organic matter started at temperatures higher than 400°C at both flow rates.…”

Section: Resultsmentioning

confidence: 99%

Structural characterization of shale oil obtained by Soxhlet extraction

Al-Saqarat

Al‐Degs

Musleh

et al. 2019

Env Prog and Sustain Energy

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Organic matter recovery by solvent extraction has been the focus of numerous research area. In this work, recovery of organic matter from oil shale was evaluated by using Soxhelt extraction. Better oil extraction was reported after preheating of the shale to 300°C in inert atmosphere. The extracted oil was fractionated to asphaltenes, aliphatics, aromatics, and polar compounds with percentages of 4.2%, 52.6%, 20.9%, and 22.3% respectively. Compared with thermal retorting, the oil obtained by solvent extraction has higher aliphatics and polar compounds. Following a proper design of experiments, oil recovery was correlated with the following experimental factors:Extraction OM% = 7.39 + 2.23 Temp + 0.20 Mass – 0.34 PS − 0.022 Ext Time + 0.13 Temp × Mass – 0.28 Temp × PS – 0.30 Mass × PS. The results indicated that preheating temperature and mass of oil shale were positively correlated with oil extraction. However, particle size/preheating temperature and mass/particle size were negatively interacted for better oil extraction. Optimum conditions for oil recovery were accomplished using tetrahydrofuran at solid‐to‐liquid ratio of 50:1 g/mL, particle size 200−250 μm, and extraction time of 8.0 hr.

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Detailed kinetic analysis of oil shale pyrolysis TGA data

Cited by 89 publications

References 62 publications

Identifying the reaction mechanism of oil-shale self-heating retorting by thermal analysis techniques

Identifying the reaction mechanism of oil-shale self-heating retorting by thermal analysis techniques

Experimental methods in chemical engineering: Thermogravimetric analysis—TGA

Structural characterization of shale oil obtained by Soxhlet extraction

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