Catalytic pyrolysis of several kinds of bamboos over zeolite NaY

Qi, Wei; Hu, Changwei; Li, G. Y.; Guo, Li; Yu, Yang; Luo, Jia; Miao, Xiaowei; Du, Ying

doi:10.1039/b510602h

Cited by 90 publications

(54 citation statements)

References 26 publications

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“…The same study by Qi et al (2006) also observed the pyrolysis of bamboo using NaY-type zeolite as a catalyst. The bamboo species used in the study were Bambusa rigida, P. pubescens, Neosinocalamus affinis, and Dendrocalamus latiflorus.…”

Section: Biocrude Oilmentioning

confidence: 63%

“…Based on the low activation energy obtained under microwave irradiation, Dong and Xiong (2014) suggested microwave heating as a promising method for biomass pyrolysis. Qi et al (2006) examined the influence of the final pyrolysis temperature of different bamboo species samples on the pyrolysis products. This study involved a fixed bed reactor and temperatures ranging from 573 °C to 873 °C.…”

Section: Biocrude Oilmentioning

confidence: 99%

See 1 more Smart Citation

Bioenergy Production from Bamboo: Potential Source from Malaysia’s Perspective

Chin

Ibrahim

Hakeem

et al. 2017

BioRes

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Global energy sectors are facing the crucial challenge of sustainability and diversification of energy resources. Seeking renewable resources with a sustainable supply is therefore a matter of the utmost concern. In this respect, bamboo, a renewable lignocellulosic material and non-food biomass, has great potential to be utilized to produce energy. Several studies have been conducted on a wide range of bamboo species and the results have shown that bamboo could potentially be used as a suitable fuel because it shares desirable fuel characteristics present in other woody biomass. Bamboo can be used as an energy source by converting it into solid, liquid, and gaseous fuels. However, to utilize bamboo as a high promise energy crop resource for biofuels, a secure and stable supply is required. Therefore, additional information on the availability, cultivation, and harvesting operations of bamboo is vital to ensure the practicability of the idea. The objective of this review is to highlight the potential of bamboo as an alternative source of bioenergy production, particularly in a Malaysian context, with emphasis on the concepts, pretreatment, and conversion technologies.

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Section: Biocrude Oilmentioning

confidence: 63%

Section: Biocrude Oilmentioning

confidence: 99%

Bioenergy Production from Bamboo: Potential Source from Malaysia’s Perspective

Chin

Ibrahim

Hakeem

et al. 2017

BioRes

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“…a) Ti and Tf represent the initial and final temperatures of decomposition where the weight loss rate is 0.1 wt-%/°C, and Tm is the temperature at which the maximum weight loss rate occurs on the DTG curve decrease of bio-oil yield in the presence of catalyst [11,12,17,18], there are also many studies reporting the increase of bio-oil via catalytic pyrolysis [19][20][21][22][23]. We [19] have studied the effect of NaY zeolite on the conversion of several kinds of bamboos, an obvious increase of bio-oil yield (from 19.7%-42.3% in the absence of catalyst to 64.1%-68.8% in the presence of NaY catalyst) was obtained.…”

Section: Increase Of Bio-oil Yield Via Catalytic Effectsmentioning

confidence: 99%

Recent advances in the catalytic pyrolysis of biomass

Luo

et al. 2010

Front. Chem. Sci. Eng.

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Biomass is considered as a renewable and alternative resource for the production of fuels and chemicals, since it is the only carbon and hydrogen containing resource that we can find in the world except for fossil resources, capable of being converted to hydrocarbons. The pyrolytic liquefaction of biomass is a promising way to convert biomass to useful products. This paper briefly surveys the present status of the direct catalytic pyrolysis for the liquefaction of biomass. The direct use of catalysts could decrease the pyrolysis temperature, increase the conversion of biomass and the yield of bio-oil, and change the distribution of the pyrolytic liquid products then improve the quality of the bio-oil obtained. The fact that biomass is in solid state present great challenges for its conversion and for the effective use of catalysts due to the bad heat transfer characteristics and bad mass transfer properties. These barriers appeal for the development of a new catalyst and new catalytic process as well as the integration of both. Process design and process intensification are of significant importance in the catalytic conversion of biomass.

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“…They could be further upgraded to motor fuels [5]. However, as lignin is difficult to be thermally degradated, the content of phenols in the pyrolytic oil was low during the direct pyrolysis of woods or bamboos [1,3,4,6].…”

Section: Introductionmentioning

confidence: 99%