Conversion of high-ash coal under steam and CO2 gasification conditions

Aranda, Gabriela N.; Grootjes, A.J.; Meijden, C.M. van der; Drift, A. van der; Gupta, Devkumar F.; Sonde, R.R.; Poojari, S.; Mitra, Chayan

doi:10.1016/j.fuproc.2015.06.006

Cited by 51 publications

(11 citation statements)

References 35 publications

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“…These values are in the range of 111-169 kJmol −1 for 800 μm particles. These values are in good agreement with the recently reported studies using different reactant concentration and origins of coal [35,36,43,47,73]. Also, the pre-exponential factors are in the range from 8.22 × 10 5 to 6.26 × 10 6 in steam ambience, 8.52 × 10 3 to 4.23 × 10 7 in blended ambience.…”

Section: Turkish Coalsupporting

confidence: 91%

Pyrolysis and Gasification Characteristics of High Ash Indian and Turkish Coals

Kandasamy¹,

Gökalp²

2018

Gasification for Low-Grade Feedstock

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Pyrolysis and gasification studies of Indian and Turkish high ash coal samples have been performed using coupled TGA-MS method. Coal samples were heated in the TGA apparatus in an argon, steam, CO 2 and blended mixtures of CO2 and steam in a temperature range from 25-1250°C with heating rates from 35 to 1000 K/min. Gas evolution measurements is performed using the mass spectrometry system. During the devolatilisation stage (350-700°C), the maximum mass loss has observed in which O 2 , CO 2 , CO, H 2 and small amount of hydrocarbon compounds are released. Char gasification is mainly influenced by operating conditions such as heating rate and reaction temperature and also the char production method, its physical structure and size and chemical composition of the char. The steam and CO 2 gasification rates of the chars are carried out at the temperatures of 850, 900, 950, and 1000°C. Three kinetic models are applied to describe the char conversion rates: volumetric model, grain model, and random pore model. The activation energy of Indian coal-char is varying from 122 to 177 kJ mol-1 under steam gasification and from 130 to 214 kJ mol-1 for CO 2 gasification. The activation energy for char-steam gasification is 156-173 kJ/ mol, whereas in the steam blended with CO 2 gasification, it ranges between 162 and 196 kJ/ mol for 3 mm particles. Similar trends are observed for the Arrhenius constant values for both sized particles.

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Section: Turkish Coalsupporting

confidence: 91%

Pyrolysis and Gasification Characteristics of High Ash Indian and Turkish Coals

Kandasamy¹,

Gökalp²

2018

Gasification for Low-Grade Feedstock

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“…In this work it was found that the shrinking core model describes the anthracite gasification process more accurately, and at the same time, it was also showed that the selection of the models is dependent on the coal rank. Aranda et al [25] studied the effect of temperature and partial pressure on the conversion and reactivity of a high-ash coal char gasification with CO2 and H2O by using a thermogravimetric analyzer and fluidized bed reactor. Results showed that the experimental data had been fitted to two conversion models (shrinking core model and volumetric reaction model).When coal char was gasified with steam, H2O molecules could enter the char micropores above 0.6nm of the char, and react at internal and external of the char, thus the volumetric reaction model and shrinking core model were all applicable for coal char gasification with steam.…”

Section: Kinetic Model Selectionmentioning

confidence: 99%

A kinetic study on lignite char gasification with CO2 and H2O in a fluidized bed reactor

Tong

Duan

et al. 2019

Applied Thermal Engineering

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Lignite char gasification experiments in CO2, H2O and their mixture were performed in a fluidized bed reactor over the temperature range of 1060K to 1210K. The active sites occupied by different gasifying agents in CO2/H2O mixture were separated and the kinetics was analyzed. Results show that the reactivity of gasification increases rapidly as the temperature rises. The average reaction rate in 50%CO2/50%H2O mixture is slower than the sum of the reaction rates separately, which indicates that CO2 and H2O compete for the same reaction active sites on the char surface. Furthermore, with an increase of temperature, the competition capacity of CO2 gasification over H2O gradually increases, as a result, CO2 gasification occupies more active sites than H2O when the temperature is higher than 1160K. Calculations of the activation energy in the kinetically controlled region based on the shrinking core model reveal that the activation energies follows the trend: N2/CO2>N2/H2O>CO2/H2O.

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“…This difference can be explained because, as the reaction of char–CO 2 proceeds, the pores open up gradually, which results in CO 2 diffusion into the internal surface of char. Therefore, there is an increasing number of micropores …”

Section: Resultsmentioning

confidence: 99%

Influence of Reactant Atmospheres and Temperature on Mechanism of Gasification of Coal Char Derived from Lignite

Wang

Luo

et al. 2016

Energy Tech

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The structural characteristics and reactivity of char derived from lignite were studied to explore the mechanism of char gasification and existence of a maximum reaction rate under an atmosphere of CO2 and H2O in a pressured thermogravimetric analyzer system. Gasification was carried out at temperatures of 1123, 1173, and 1223 K. When the temperature was below 1173 K, the mechanism of char gasification in the mixture of H2O and CO2 proceeded through the separate active sites assumption, whereas if the temperature was higher than 1173 K, it favored common active sites. The reaction rate increased and then decreased during the remaining time, which was in agreement with the total surface area. The existence of a maximum reaction rate depended highly on the surface area: a larger surface area resulted in a higher reaction rate. The total surface in H2O was the largest and the addition of CO2 inhibited the formation of pores. The reaction of char with CO2 mainly took place on the microporous surface first, and then took place on a mesoporous surface, and the reaction of char with H2O took place on both the micro‐ and mesoporous surfaces simultaneously.

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Conversion of high-ash coal under steam and CO2 gasification conditions

Cited by 51 publications

References 35 publications

Pyrolysis and Gasification Characteristics of High Ash Indian and Turkish Coals

Pyrolysis and Gasification Characteristics of High Ash Indian and Turkish Coals

A kinetic study on lignite char gasification with CO2 and H2O in a fluidized bed reactor

Influence of Reactant Atmospheres and Temperature on Mechanism of Gasification of Coal Char Derived from Lignite

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