Energy Conversion Efficiency of Pyrolysis of Chicken Litter and Rice Husk Biomass

Weldekidan, Haftom; Strezov, Vladimir; He, Jing; Kumar, Ravinder; Sarkodıe, Samuel Asumadu; Doyi, Israel; Jahan, Sayka; Kan, Tao; Town, Graham

doi:10.1021/acs.energyfuels.9b01264

Cited by 23 publications

(15 citation statements)

References 42 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…On the other hand, it is noteworthy that the energy required to heat the biomass to the operating temperature of pyrolysis (i.e., 500 °C) and for biomass pyrolysis reaction are around 0.98 MJ kg −1 and 1.01 MJ kg −1 respectively. Similar results have been reported in Yang et al (2013) and Weldekidan et al (2019), where they estimated the heat required for biomass pyrolysis by using TGA-DSC experiment. Their results concluded that the energy demand for heating the rice husk and chicken litter to the pyrolysis temperature of 500 °C were 0.8 MJ kg −1 and 1.2 MJ kg −1 respectively, while the heat energy consumed for pyrolysis process of five different biomass samples was in the range of 1.1-1.6 MJ kg −1 at pyrolysis temperature between 500 and 550 °C.…”

Section: A Base Case Study Of the Biomass Pyrolysis-solid Oxide Fuel ...supporting

confidence: 85%

Thermodynamic analysis of a novel integrated biomass pyrolysis-solid oxide fuel cells-combined heat and power system for co-generation of biochar and power

et al. 2022

View full text Add to dashboard Cite

Biochar derived from pyrolysis or gasification has been gaining significant attention in the recent years due to its potential wide applications for the development of negative emissions technologies. A new concept was developed for biochar and power co-generation system using a combination of biomass pyrolysis (BP) unit, solid oxide fuel cells (SOFCs), and a combined heat and power (CHP) system. A set of detailed experimental data of pyrolysis product yields was established in Aspen Plus to model the BP process. The impacts of various operating parameters including current density (j), fuel utilization factor (Uf), pyrolysis gas reforming temperature (Treformer), and biochar split ratio (Rbiochar) on the SOFC and overall system performances in terms of energy and exergy analyses were evaluated. The simulation results indicated that increasing the Uf, Treformer, and Rbiochar can favorably improve the performances of the BP-SOFC-CHP system. As a whole, the overall electrical, energy and exergy efficiencies of the BP-SOFC-CHP system were in the range of 8–14%, 76–78%, and 71–74%, respectively. From the viewpoint of energy balance, burning the reformed pyrolysis gas can supply enough energy demand for the process to achieve a stand-alone BP-SOFC-CHP plant. In case of a stand-alone system, the overall electrical, energy and exergy efficiencies were 5.4, 63.9 and 57.8%, respectively, with a biochar yield of 31.6%.

show abstract

Section: A Base Case Study Of the Biomass Pyrolysis-solid Oxide Fuel ...supporting

confidence: 85%

Thermodynamic analysis of a novel integrated biomass pyrolysis-solid oxide fuel cells-combined heat and power system for co-generation of biochar and power

et al. 2022

View full text Add to dashboard Cite

show abstract

“…In general, over 70% of the municipal waste plastic was converted into oil at each trial of the process with the entire pyrolytic system having an average overall conversion efficiency of 96.67%. Similar efficiency results were achieved by Weldekidan et al (2019) using chicken litter and rice husk as feed.…”

Section: Conversion Efficiencysupporting

confidence: 79%

Design, Fabrication and Operational Evaluation of a Co-Pyrolysis System for Waste-Plastics Derived Fuels: A Study of Edo North

Otoikhian¹,

Amune²,

Edogamhe³

et al. 2022

American Journal of Engineering and Applied Sciences

View full text Add to dashboard Cite

This research work designed, developed and assessed the performance of a co-pyrolysis system generating waste-plastic extract fuels from mixed Municipal Waste Plastics (MWP) while evaluating High-Density Polyethylene (HDPE), Polypropylene (PP) and Polystyrene (PS) as the main municipal waste plastic sources. The materials selected for the reactor were carefully studied to meet the pyrolysis system's strength, operability and safety requirements. The equipment was put through its paces in three trials, using 2kg of mixed municipal waste plastics each. The temperature was optimally constant at 450°C for three hours. The equipment had a functional conversion efficiency (wt %) of 73.17%, a waste reduction efficiency (wt %) of 86.3% and oil recovery of 0.90L oil/kg MWP, according to the test results. As a result of its re-cracking process, which recycles heavy molecular weight compounds back into the reactor, this reactor was built in such a manner that only compounds in the carbon range of C1 20 may be created. This process was discovered to have a major impact on the product's distribution. Plastic fuels generated from co-mingled municipal waste plastics had similar characteristics with diesel and based on the characterization and comparative research done in this study.

show abstract

“…Pyrolysis efficiency is the thermal efficiency obtained as the ratio of the difference between the overall heating values of the pyrolytic products and the total thermal energy utilized for processing the sample. Pyrolysis is a well-known process of producing high energy-density biofuels and chemicals [24]. Wang et al [25] presented a comprehensive overview of the pyrolysis mechanisms of three biopolymers in biomass materials and highlighted the complexities in their structure.…”

mentioning

confidence: 99%

Progress of the Pyrolyzer Reactors and Advanced Technologies for Biomass Pyrolysis Processing

et al. 2021

View full text Add to dashboard Cite

In the future, renewable energy technologies will have a significant role in catering to energy security concerns and a safe environment. Among the various renewable energy sources available, biomass has high accessibility and is considered a carbon-neutral source. Pyrolysis technology is a thermo-chemical route for converting biomass to many useful products (biochar, bio-oil, and combustible pyrolysis gases). The composition and relative product yield depend on the pyrolysis technology adopted. The present review paper evaluates various types of biomass pyrolysis. Fast pyrolysis, slow pyrolysis, and advanced pyrolysis techniques concerning different pyrolyzer reactors have been reviewed from the literature and are presented to broaden the scope of its selection and application for future studies and research. Slow pyrolysis can deliver superior ecological welfare because it provides additional bio-char yield using auger and rotary kiln reactors. Fast pyrolysis can produce bio-oil, primarily via bubbling and circulating fluidized bed reactors. Advanced pyrolysis processes have good potential to provide high prosperity for specific applications. The success of pyrolysis depends strongly on the selection of a specific reactor as a pyrolyzer based on the desired product and feedstock specifications.

show abstract

Energy Conversion Efficiency of Pyrolysis of Chicken Litter and Rice Husk Biomass

Cited by 23 publications

References 42 publications

Thermodynamic analysis of a novel integrated biomass pyrolysis-solid oxide fuel cells-combined heat and power system for co-generation of biochar and power

Thermodynamic analysis of a novel integrated biomass pyrolysis-solid oxide fuel cells-combined heat and power system for co-generation of biochar and power

Design, Fabrication and Operational Evaluation of a Co-Pyrolysis System for Waste-Plastics Derived Fuels: A Study of Edo North

Progress of the Pyrolyzer Reactors and Advanced Technologies for Biomass Pyrolysis Processing

Contact Info

Product

Resources

About