Integrated Leaching and Thermochemical Technologies for Producing High-Value Products from Rice Husk: Leaching of Rice Husk with the Aqueous Phases of Bioliquids

Gao, Weiqi; Li, Hui; Karnowo, -; Song, Bing; Zhang, Shu

doi:10.3390/en13226033

Cited by 12 publications

(9 citation statements)

References 54 publications

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“…Thermogravimetric (TG) and differential thermal gravity (DTG) curves showed a difference in thermal behaviors between RH and CDR (Figure 1). RH consists of (hemi)cellulose, lignin and other organic minorities [36,37] so that the weight loss of RH can be divided into three main stages (Figure 1a). The release of adsorbed gases and water vapor occurred from 50 to 218 • C, followed by the thermal decomposition of volatiles from (hemi)cellulose with the range of 218 to 409 • C (weight loss = 57.3%).…”

Section: Individual Samplesmentioning

confidence: 99%

Quest for the Co-Pyrolysis Behavior of Rice Husk and Cresol Distillation Residue: Interaction, Gas Evolution and Kinetics

Cui

Zhang

et al. 2022

Energies

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With the tremendous prosperity of industry, more and more hazardous waste is discharged from industrial production processes. Cresol distillation residue is a typical industrial hazardous waste that causes severe pollution without proper treatment. Herein, the co-pyrolysis of rice husk and cresol distillation residue was studied using thermogravimetry–mass spectrometry and kinetic studies. The Coats and Redfern method was employed to calculate the activation energy. The results indicated that the pyrolysis process of cresol distillation residue and RH/CDR (Rice Husk and Cresol Distillation Residue) blends can be divided into four stages and three stages for RH. The introduction of RH not only improved the thermo-stability of cresol distillation residue at a low temperature but also reduced the activation energy of the blends. The activation energy was the lowest when the proportion of rice husk in the blend was 60%. The main gaseous pyrolysis products included CH4, H2O, C2H2, CO2, C3H6 and H2. There existed an unusual combination of synergistic and inhibitive interactions between RH and cresol distillation residue, respectively, within different temperature ranges. The synergistic interaction decreased the reaction’s activation energy, whereas the inhibitive interaction reduced the emission of main gaseous products, such as CH4 and CO2. It was concluded that the addition of RH was conducive to improving the pyrolytic performance of cresol distillation residue and the resource utilization of cresol distillation residue.

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Section: Individual Samplesmentioning

confidence: 99%

Quest for the Co-Pyrolysis Behavior of Rice Husk and Cresol Distillation Residue: Interaction, Gas Evolution and Kinetics

Cui

Zhang

et al. 2022

Energies

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“…The hydrothermal liquefaction of RH was carried out using a 100 mL stirred autoclave as detailed elsewhere. 18 In brief, 3 g of RH and 50 mL of deionized water were loaded into the autoclave for each run, then degassed using N 2 (30 min). 22 After degassing, the reactor was pressurized to 1 MPa with N 2 , followed by heating to 280 °C (5 °C min −1 , holding for 10 min) and the stirring speed was constant at 175 rpm.…”

Section: Heavy Bio-oil From Hydrothermal Treatmentmentioning

confidence: 99%

“…The slow pyrolysis of RH samples (HBO-SP) was carried out in a tubular furnace system as illustrated in a previous paper. 18 Samples of RH (30 g) were pre-loaded into the reactor, then heated to 110 °C (10 °C min −1 ) and held for 30 min, followed by heating to 500 °C with the same heating rate (holding for 60 min). The bio-oil was collected and placed in an ice bath for cooling.…”

Section: Heavy Bio-oils From Slow Pyrolysismentioning

confidence: 99%

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Heavy bio‐oils as bio‐binders for rice husk densification: Parameter optimization, binding mechanisms and subsequent pyrolysis and combustion performances

Yan

Song

et al. 2022

Biofuels Bioprod Bioref

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Densification is widely considered as a means to improve the bulk energy density and transportation efficiency of biomass, while the durability and fuel quality of densified biomass often need to be further improved by the addition of binders. In this study, the heavy fractions of bio‐oils from slow pyrolysis (HBO‐SP) and hydrothermal treatment (HBO‐HT) of rice husk (RH) are used as bio‐binders for RH densification. Optimal parameters are determined based on Taguchi methods. They are: densification temperature 130 °C, densification pressure 200 MPa, bio‐binder content 8%, particle size 0.4–0.6 mm, and using HBO‐HT as the binder. The obtained pellets showed a high drop resistance of 99.8% and the binding mechanism is governed by solid bridges between particles. Heavy bio‐oils are deformed and re‐solidified and function as a binder for RH densification. The RH/HBO‐HT pellets showed lower activation energy for pyrolysis as well as lower ignition temperature (292.81 °C compared with 298.34 °C for RH pellets). The higher heating value of pellets was increased from 14.99 to 16.29 MJ kg−1 with 8 wt% HBO‐HT. The co‐densification of heavy bio‐oils and RH provides an approach for producing more qualified solid biofuels from agriculture wastes. © 2022 Society of Chemical Industry and John Wiley & Sons, Ltd

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“…Lignin contains phenolic hydroxyl groups, phenol alcohol groups, carboxylic acid groups and carbonyl groups 24 . Lignin is a typical multi‐group ligand which has the ability to form lignin chelate soluble salts with metal cations under alkaline conditions, 25 hence lignin can be dissolved in alkaline solution. In alkaline media, the bonds between carbohydrates and lignin are easy to break.…”

Section: Lignin Extraction By Chemical Pretreatmentmentioning

confidence: 99%

Exploration of mechanisms of lignin extraction by different methods

Kong

et al. 2021

Environ Prog Sustainable Energy

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Due to a combination of rapid consumption of fossil fuels such as coal and oil with gradual increase in people's awareness of environmental protection, the research for substitute resources has become a hot spot. Because of their abundant sources of raw materials, fast regeneration rate and low greenhouse gas emissions, biomass resources have drawn much attentions. Woody fiber is one of the richest renewable biomass on earth, in which lignin is the largest renewable aromatic compound resource, therefore possessing a very broad application prospect. Nowadays, a large number of reviews on lignin extraction methods have been written while there are few explorations on the mechanisms behind those methods. Thus, the principles of several typical lignin extraction methods were described in this article. These principles were explored with the hope to provide a reference for future development of lignin extraction.

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Integrated Leaching and Thermochemical Technologies for Producing High-Value Products from Rice Husk: Leaching of Rice Husk with the Aqueous Phases of Bioliquids

Cited by 12 publications

References 54 publications

Quest for the Co-Pyrolysis Behavior of Rice Husk and Cresol Distillation Residue: Interaction, Gas Evolution and Kinetics

Quest for the Co-Pyrolysis Behavior of Rice Husk and Cresol Distillation Residue: Interaction, Gas Evolution and Kinetics

Heavy bio‐oils as bio‐binders for rice husk densification: Parameter optimization, binding mechanisms and subsequent pyrolysis and combustion performances

Exploration of mechanisms of lignin extraction by different methods

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