Combustion behavior and kinetics of low-lipid microalgae via thermogravimetric analysis

Gai, Chao; Liu, Zhengang; Han, Gang; Peng, Nana; Fan, Aonan

doi:10.1016/j.biortech.2015.01.045

Cited by 88 publications

(27 citation statements)

References 36 publications

(47 reference statements)

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“…It suggests that CP is preferable to SP during the thermal degradation process as more volatile matters could be converted into target products. And it is consistent with the results of kinetic analysis of thermal-chemical conversion of CP and SP [13,16]. According to Kumar et al [17], the solid residue is mainly composed of ash and bio-char.…”

Section: Yields Of Product Fractionssupporting

confidence: 87%

An investigation of reaction pathways of hydrothermal liquefaction using Chlorella pyrenoidosa and Spirulina platensis

Gai

Zhang

Chen

et al. 2015

Energy Conversion and Management

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252

109

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a b s t r a c tLow-lipid microalgae can be successfully converted to bio-crude oil in a hydrothermal liquefaction (HTL) environment. This study examined the behavior of hydrothermal liquefaction of two low-lipid content microalgae in subcritical water between 200°C and 320°C at 20°C intervals. Under these conditions, the chemical composition and functional groups for the bio-crude oil and aqueous fraction were analyzed. Results indicated that reaction temperature greatly affected the distribution of chemical composition and functional groups of HTL bio-crude oil and aqueous fraction. The bio-crude oil with a higher percentage of aliphatic functional groups was obtained at higher reaction temperatures (280-320°C). Besides, the aqueous fraction recovered under the same operating conditions had a lower concentration of nitrogenous organic compounds (NOCs) with two or more methyl groups. The general reaction network for HTL of low-lipid microalgae was proposed. The specific reaction pathways for microalgae substrates were analyzed in terms of lipid, protein and non-fibrous carbohydrate based on the spectral analysis.

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Section: Yields Of Product Fractionssupporting

confidence: 87%

An investigation of reaction pathways of hydrothermal liquefaction using Chlorella pyrenoidosa and Spirulina platensis

Gai

Zhang

Chen

et al. 2015

Energy Conversion and Management

Self Cite

252

109

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show abstract

“…Table 2 illustrated that the average value of apparent activation energy (16.34 kJ/mol) for propane was lower than that of ethylene (17.59 kJ/mol), then accompanied with methane (23.27 kJ/mol) and hydrogen (69.55 kJ/mol). The reaction rate of a reaction with lower apparent activation energy is faster due to the lesser energy required to break down the chemical bonds between atoms [39]. According to Anis and Zainal [28], the formation of hydrocarbons is more favorable than that of hydrogen during conversion of toluene, which is consistent with the results in the present study.…”

Section: Variation Of Apparent Activation Energiessupporting

confidence: 82%

Kinetic study on thermal decomposition of toluene in a micro fluidized bed reactor

Gai

Dong

Fan

et al. 2015

Energy Conversion and Management

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a b s t r a c tThis study concerned the pyrolysis behavior of toluene as the tar model compound. Pyrolysis experiments were carried out in a micro fluidized bed reactor (MFBR) under an isothermal condition. Pyrolysis kinetics for the gas components, including hydrogen, methane, ethylene and propane were calculated based on the model-free and model-fitting methods. Results showed that methane and ethylene were the major gas components at lower temperatures (650-800°C) while propane and ethylene were the main composition of pyrolysis gas mixture at higher temperatures (800-850°C). For the range of conversion fraction (20-80%), the apparent activation energy of propane (16.34 kJ/mol) was lower than that of ethylene (17.59 kJ/mol), then accompanied with methane (23.27 kJ/mol) and hydrogen (69.55 kJ/mol). The most probable reaction mechanism for the generation of hydrogen was three-dimensional diffusion while the evolution profiles of methane could be described by the mechanism of nucleation and growth. Chemical reaction was the most probable reaction mechanism for ethylene and propane. Results from the present study indicated that MFBR can enable a quicker reaction within the reactor than other traditional approaches. The generation of propane is easier to proceed compared to other hydrocarbons with smaller carbon numbers during pyrolysis of toluene. A comparison of kinetic models and experimental results suggested that the developed models closely predicted the thermal cracking behavior of toluene.

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“…Furthermore, several studies have shown the benefits and sustainability of the integration of microalgae pyrolysis processes within the biorefinery framework due to their capacity of integration with transesterification and fermentation processes [23][24][25]. Together with pyrolysis, microalgae combustion seems another viable technology for microalgae valorization [11,26].…”

Section: Background In Thermochemical Conversion Of Microalgae By Thementioning

confidence: 99%

Energetic, economic and environmental assessment of the pyrolysis and combustion of microalgae and their oils

López-González

Puig-Gamero

Acién

et al. 2015

Renewable and Sustainable Energy Reviews

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Combustion behavior and kinetics of low-lipid microalgae via thermogravimetric analysis

Cited by 88 publications

References 36 publications

An investigation of reaction pathways of hydrothermal liquefaction using Chlorella pyrenoidosa and Spirulina platensis

An investigation of reaction pathways of hydrothermal liquefaction using Chlorella pyrenoidosa and Spirulina platensis

Kinetic study on thermal decomposition of toluene in a micro fluidized bed reactor

Energetic, economic and environmental assessment of the pyrolysis and combustion of microalgae and their oils

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