Your search keyword '"cryogenic pretreatment"' showing total 3 results

1. Characteristics of pyrolysis products of biomass under cryogenic pretreatment using liquid nitrogen

Author

Tao XU, Lingyun CHEN, Xiuren ZHENG, Yongping WU, Panshi XIE, and Jie CHEN

Subjects

biomass, fast pyrolysis, cryogenic pretreatment, bio-oil, product composition, Geology, QE1-996.5, Mining engineering. Metallurgy, TN1-997

Abstract

Biomass, as a renewable energy source, features wide availability, multiple functions, and carbon neutralization. The high-value resource utilization of biomass is conducive to reducing reliance on high-carbon fossil energy, ensuring national energy security, and curbing environmental pollution, aligning with the needs of China's "dual carbon" national strategy. Pyrolysis, as the foundation of biomass thermochemical conversion, is one of the best technologies to achieve a high-value utilization of biomass energy. However, it has some core issues such as low bio-oil yield and poor quality. To overcome these problems, a cryogenic technology was innovatively applied to the field of biomass pyrolysis, and a new biomass oil production method of "cryogenic + fast pyrolysis" was proposed to increase the yield and quality of pyrolytic bio-oil. Taking two types of crop straw as experimental research objects, the rapid freezing pretreatment method with liquid nitrogen was adopted to study the evolution mechanism of the product distribution and composition of biomass pyrolysis under cryogenic pretreatment. The experiments show that compared with conventional pyrolysis, the increase in the bio-oil yield after cryogenic pretreatment of biomass pyrolysis can reach 14.16% to 23.73%, and the cryogenic pretreatment temperature has a positive correlation with the bio-oil yield, and the maximum bio-oil yield (22.3% to 26.3%) is reached at −90 ℃, exceeding the bio-oil yield of the aluminum method by 8.50% to 22.71%. The cryogenic pretreatment has a significant transformation effect on the composition of the bio-oil, and the content of benzene series (BTEX) and phenolic substances in the bio-oil composition increases significantly, with the maximum increase of 43.61% and 12.45%, respectively. The cryogenic pretreatment of liquid nitrogen inhibited the release of CO2 and CO in biomass pyrolysis gas, and the proportion of components decreased by 7.2%−29.7%. In addition, the inhibition of the release of CO2 and CO in the biomass pyrolysis gas and the increase of CH4 and H2 by cryogenic pretreatment increase by 0.2% to 14.7%. Moreover, the increase in C content and the decrease in O content in the solid product under cryogenic pretreatment are conducive to improving the combustibility of biochar and reducing its risk of spontaneous combustion.

Published

2024

2. Cryogenic pretreatment of keratinous waste for enhanced methane production.

Author

Kuzmanova, Elena, Akunna, Joseph C., and Zhelev, Nikolai

Subjects

METHANE, CRYOGENICS, KERATIN, BIODEGRADATION, ANAEROBIC digestion, MOLECULAR structure

Abstract

Signifcant amount of keratinous waste is generated every year, derived from various sources. The structure and complexity of a wool fibre as such, provides resistance and challenge for bacteria to degrade into compounds that can be metabolised. That is why cryogenic pretreatment was applied to improve the digestibility of four sheep breeds fibres. In addition to structural and molecular differences between the untreated, raw wool and treated samples, the effect of pretreatment on methane production for these raw fibres was investigated by anaerobic batch digestion at 37°C. As a response of cryogenic application, soluble protein content had increased in each pretreated sample in comparison with untreated samples, whereas the molecular structure of wool fibres remains intact. The degradation is additionally facilitated by structural changes in the morphological structure. Furthermore, treatment resulted in increased methane production for all treated wool fibres. [ABSTRACT FROM AUTHOR]

Published

2017

3. Cryogenic pretreatment of keratinous waste for enhanced methane production

Author

Elena Kuzmanova, Joseph Akunna, and Nikolai Zhelev

Subjects

cryogenic pretreatment, wool, methane productio, Biology (General), QH301-705.5

Published

2017