Effects of Briquetting and High Pyrolysis Temperature on Hydrolysis Lignin Char Properties and Reactivity in CO-CO2-N2 Conditions

Carbonaceous reductants for pyrometallurgical applications are usually obtained from fossil-based sources. The most important properties of the reductants greatly depend on the application and the feeding of the reductant into the process. However, the mechanical strength, calorific value, fixed carbon content, and reactivity of the reductant are the properties that usually define the applicability of the reductant for different processes. The reactivity of the biochars is usually high in comparison to metallurgical coke, which may restrict the applicability of the biochar in reduction processes. One cause of the higher reactivity is the higher surface area of the biochars, which can be suppressed with agglomeration treatment, e.g., briquetting. In this work, hydrolysis lignin was used for slow pyrolysis experiments to produce biochars. The biochars were pyrolyzed in briquetted form and in as-received form at various temperatures. The reactivity values of the biochars were tested in dynamic reactivity tests in a CO-CO2-N2 gas atmosphere at temperatures of up to 1350 °C. It was found that the yield of the hydrolysis lignin char only decreased by 3.36 wt% when the pyrolysis temperature was elevated from 600 to 1200 °C, while a decrease in yield of 4.88 wt% occurred when the pyrolysis temperature was elevated from 450 to 600 °C. The mass loss of hydrolysis lignin biochar in the reactivity experiment in CO-CO2-N2 atmosphere was significantly decreased from 79.41 wt% to 56.80 wt% when the hydrolysis lignin was briquetted before the slow pyrolysis process and the temperature of the pyrolysis process was elevated from 600 to 1200 °C. This means that the mass loss of the material was suppressed by 22.61 wt% due to the higher pyrolysis temperature and briquetting process.

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Characterization of Banana Peels Wastes as Potential Slow Pyrolysis Feedstock

Journal of Sustainable Development ◽

10.5539/jsd.v11n2p14 ◽

2018 ◽

Vol 11 (2) ◽

pp. 14 ◽

Cited By ~ 13

Author(s):

Isa Kabenge ◽

Godfrey Omulo ◽

Noble Banadda ◽

Jeffrey Seay ◽

Ahamada Zziwa ◽

...

Keyword(s):

Value Added ◽

Calorific Value ◽

Volatile Matter ◽

Banana Peel ◽

Fixed Carbon ◽

Slow Pyrolysis ◽

Pyrolysis Feedstock ◽

Lower Heating ◽

Banana Wastes

Uganda is the world’s second largest producer and consumer of banana after India. This has resulted into vast quantities of banana wastes, including the leaves, pseudostem, stalks, rejected and rotten fruits and the fruit peels. This study focuses on the characterization of banana peels to yield banana peels vinegar (BPV), tar and biochar as value added products that can be useful to farmers. Dried banana peels were characterized via proximate, ultimate, lignocellulosic, thermogravimetric (TG), and calorific value analyses. The obtained results showed that the volatile matter and fixed carbon contents were 88.02% and 2.70% while carbon, nitrogen and sulphur were 35.65%, 1.94% and 20.75 ppm respectively. The hemicellulose, cellulose and lignin contents were 41.38%, 9.90% and 8.90% while the higher and lower heating values were 16.15 MJ/kg and 14.80 MJ/kg. The maximum devolatilization rate in the banana peel biomass occurred in the temperatures range of 450–550oC which was taken as the slow pyrolysis regime temperature. The high levels of fixed carbon, volatile matter and ash contents were strong indicators that banana wastes are adequate feedstock for pyrolysis work to yield bio-infrastructure products. Similarly, the lignin, cellulose and hemicellulose fractions had significant correlation between the biomass heating values and the eventual chemical compounds present BPV and biochar. The characterization properties of the banana peels are akin to the leaves and pseudostem and thus are suitable for pyrolysis process.

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Effect of Varying H2S Content on High-Temperature Corrosion of Ferritic and Austenitic Alloys in a Simulated Pyrolysis Process of Post-Consumer Plastics

BHM Berg- und Hüttenmännische Monatshefte ◽

10.1007/s00501-021-01126-x ◽

2021 ◽

Author(s):

Manuela Nimmervoll ◽

Gregor Mori ◽

Edith Bucher ◽

Stefan Hönig ◽

Roland Haubner

Keyword(s):

Mass Loss ◽

Process Conditions ◽

Pyrolysis Process ◽

Reactor Material ◽

Gas Atmosphere ◽

Austenitic Alloys ◽

Scale Test ◽

Reactor Zone ◽

Cracking Process ◽

Increasing Temperature

AbstractThe alloys K90941 and N08811 were tested under conditions simulating a pyrolysis process of post-consumer plastics. Impurities in the plastic feedstock like chlorine containing materials or organic components yield HCl and H2S respectively during the cracking process. The reactor material must be able to withstand these harsh corrosive conditions.In lab-scale test equipment, process conditions of the reactor zone of the pyrolysis process were simulated at temperatures of 420 °C and 580 °C for 72 h. The gas atmosphere consisted of either 200 ppm or 20000 ppm H2S and 3.8 vol% HCl, 1.9 vol% CO2, 0.3 vol% CO, 2.8 vol% H2, bal. N2. After the corrosion experiments, the samples were analyzed by metallography, SEM/EDX, and XRD. Additionally, the mass loss was evaluated. Results show that the ferritic K90941 is more aggressively attacked than the austenitic N08811 and that for both materials the mass loss rises with increasing H2S content in the gas atmosphere and increasing temperature.

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Evolution of the Mass Loss Rate During Atmospheric and Pressurized Slow Pyrolysis of Wheat Straw in a Bench-Scale Reactor

Jornada de Jóvenes Investigadores del I3A ◽

10.26754/jji-i3a.201802836 ◽

2018 ◽

Vol 6 ◽

Author(s):

Gianluca Greco ◽

Joan J. Manyá ◽

Belén Gonzaléz ◽

María Videgain

Keyword(s):

Mass Loss ◽

Wheat Straw ◽

Loss Rate ◽

Mass Loss Rate ◽

Absolute Pressure ◽

Pyrolysis Process ◽

Slow Pyrolysis ◽

Bench Scale ◽

Pyrolysis Of Biomass ◽

Scale Reactor

A deep study focused on the significant effect of the absolute pressure on the yield of produced gas during the slow pyrolysis of biomass was carried out. In addition, the evolution of the mass loss rate linked to the pyrolysis process was also analyzed.

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The Effects of Temperature and Heating Rate on the Preparation of Stalk Char

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.496.88 ◽

2012 ◽

Vol 496 ◽

pp. 88-93

Author(s):

Jian Pan ◽

Lin Wang

Keyword(s):

Heating Rate ◽

Pyrolysis Temperature ◽

Calorific Value ◽

Product Yield ◽

Proximate Analysis ◽

High Yield ◽

Heating Rates ◽

Fixed Carbon ◽

Experimental Parameters ◽

Effects Of Temperature

The pyrolysis of three stalk was studied to estimate the eﬀect of pyrolysis conditions on product yield, calorific value and proximate analysis. Heating rate and pyrolysis temperature were the main experimental parameters. According to the test, when the heating rates were at 5, 10 and 15°C/min, the low heating rate reacted more thoroughly, got high yield and kept more energy. As the pyrolysis temperature rising; namely 200,300,400 and 500°C;the fixed carbon and gross calorific value were increasing to be 68% and 24.72 MJ/Kg respectively, but the yield was decreasing.

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Effect of Pyrolysis Temperature and Residence Time on Bio-char Obtained from Pyrolysis of Shredded Cotton Stalk

International Research Journal of Pure and Applied Chemistry ◽

10.9734/irjpac/2020/v21i1330236 ◽

2020 ◽

pp. 10-28

Author(s):

J. M. Makavana ◽

P. N. Sarsavadia ◽

P. M. Chauhan

Keyword(s):

Residence Time ◽

Pyrolysis Temperature ◽

Calorific Value ◽

Volatile Matter ◽

Quality Parameters ◽

Ash Content ◽

Cotton Stalk ◽

Fixed Carbon ◽

Heating Value

Bio-char is carbon-rich product generated from biomass through batch type slow pyrolysis. In this study, the effects of pyrolysis temperature and residence time on the yield and properties of bio-chars obtained from shredded cotton stalks were investigated. Safely said that the quality of bio-char of shredded cotton stalk obtained at 500°C temperature and 240 min is best out of the all experimental levels of variables of temperature and residence time. At this temperature and residence time, the quality of bio-char in terms higher heating value (8101.3cal /g or 33.89 MJ/kg), nitrogen (1.56%), Carbon (79.30%), and C/N ratio (50.83) respectively. The quality of bio-char for various applications is discussed along with different quality parameters. The bio-char could be used for the production of activated carbon, in fuel applications, and water purification processes. Average bulk density of whole cotton stalk and shredded cotton stalk was found as 29.90 kg/m3 and 147.02 kg/m3 respectively. Thus density was increased by 3.91 times. The value of pH, EC and CEC of shredded cotton stalk biomass was found as 5.59, 0.03 dS/m and 38.84 cmol/kg respectively. Minimum and maximum values pH, EC and CEC of its bio-char was found as 5.85 to9.86, 0.04 to 0.10 dS/m and 38.02 to 24.39 cmol/kg at 200°C and 60 min and; 500°C and 240 min temperature and residence time respectively. Moisture content, ash content, volatile matter and fixed carbon of shredded cotton stalk biomass were found as, 12.5, 5.27, 80.22, and 14.51 (%, d.b) respectively. The minimum and maximum value of bio-char in terms of ash content, volatile matter and fixed carbon of bio-char were found as 5.5 to 15.56, 48.02 to 79.48 and 15.02 to 36.40 (%, d.b) respectively. Calorific value of cotton stalk biomass was found as 3685.3 cal /g. The minimum and maximum higher heating value of its bio-char was found as 4622.0 cal/ g and 8101.3 cal/g at 200°C and 60 min and; 500˚C and 240 min temperature and residence time.

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Effects of pyrolysis temperature on production and physicochemical characterization of biochar derived from coconut fiber biomass through slow pyrolysis process

Biomass Conversion and Biorefinery ◽

10.1007/s13399-020-01116-y ◽

2020 ◽

Author(s):

Sajib Aninda Dhar ◽

Tamjid Us Sakib ◽

Lutfun Naher Hilary

Keyword(s):

Pyrolysis Temperature ◽

Physicochemical Characterization ◽

Pyrolysis Process ◽

Coconut Fiber ◽

Slow Pyrolysis

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Characteristics of coconut frond as a potential feedstock for biochar via slow pyrolysis

Malaysian Journal of Fundamental and Applied Sciences ◽

10.11113/mjfas.v14n4.1014 ◽

2018 ◽

Vol 14 (4) ◽

pp. 408-413

Author(s):

Nur Syairah Mohamad Aziz ◽

Adilah Shariff ◽

Nurhayati Abdullah ◽

Nurhidayah Mohamed Noor

Keyword(s):

Weight Loss ◽

Volatile Matter ◽

Ash Content ◽

Pyrolysis Process ◽

Fixed Carbon ◽

Heating Value ◽

Slow Pyrolysis ◽

High Heating Value ◽

Bio Oil ◽

High Heating

The aim of this study is to investigate the potential of coconut frond as a feedstock for biochar production via slow pyrolysis process. Proximate, elemental and thermogravimetric analysis were performed to evaluate the chemical and thermal properties of the coconut frond. The percentage of its lignocellulosic component and high heating value were determined. Surface morphology of coconut frond was examined using field emission scanning electron microscope (FESEM). Coconut frond (CF) contains 78.03±3.91 d.b. wt% of volatile matter, 4.96±0.07 d.b. wt% of ash content and 17.01±3.86 d.b. wt% of fixed carbon. Elemental analysis revealed a sulfur content of 0.94±0.12 %, while the percentage of nitrogen is 0.46±0.33%. The composition of carbon and hydrogen are 34.0±6.22 % and 7.71±0.34 % respectively. The high heating value of CF is 17.77±0.40 MJ/kg. CF consists of 43.91±1.80 % cellulose, 31.58±1.20 % hemicellulose, and 18.15±0.60 % lignin. From thermogravimetric (TG) analysis, it is apparent that the weight loss of CF occurred prominently in the temperature range 200°C - 400°C. The peaks of the DTG curve at 281.75±0.35 °C and 334.08±0.35°C indicate the weight loss of coconut frond sample due to the degradation of hemicellulose and cellulose, respectively. The FESEM images of CF show its fibrous strands are compact with a few large pores with diameters around 42.5 - 48.1 μm large pores in the center of the CF sample. The results of the analysis show that CF has a potential as a feedstock for biochar production via slow pyrolysis. CF also can be used in other application such as syngas and bio-oil production due to the low lignin percentage and high volatile percentage.

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Assessment of Cow Dung Pellets as a Renewable Solid Fuel in Direct Combustion Technologies

Energies ◽

10.3390/en14041192 ◽

2021 ◽

Vol 14 (4) ◽

pp. 1192

Author(s):

Aneta Szymajda ◽

Grażyna Łaska ◽

Magdalena Joka

Keyword(s):

Renewable Energy ◽

Calorific Value ◽

Cow Dung ◽

Fixed Carbon ◽

Direct Combustion ◽

Potential Source ◽

Novel Approach ◽

Combustion Tests ◽

Promising Source ◽

Compaction Properties

Recently, biomass application as a renewable energy source is increasing worldwide. However, its availability differs in dependence on the location and climate, therefore, agricultural residues as cow dung (CD) are being considered to supply heat and/or power installation. This paper aims at a wide evaluation of CD fuel properties and its prospect to apply in the form of pellets to direct combustion installations. Therefore, the proximate, ultimate composition and calorific value were analyzed, then pelletization and combustion tests were performed, and the ash characteristics were tested. It was found that CD is a promising source of bioenergy in terms of LHV (16.34 MJ·kg−1), carbon (44.24%), and fixed carbon (18.33%) content. During pelletization, CD showed high compaction properties and at a moisture content of 18%,and the received pellets’ bulk density reached ca. 470 kg·m−3 with kinetic durability of 98.7%. While combustion, in a fixed grate 25 kW boiler, high emissions of CO, SO2, NO, and HCl were observed. The future energy sector might be based on biomass and this work shows a novel approach of CD pellets as a potential source of renewable energy available wherever cattle production is located.

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