The ignitability, fuel ratio and ash fusion temperatures of torrefied woody biomass

Adeleke, A. A.; Odusote, Jamiu Kolawole; Ikubanni, P.P.; Lasode, Olumuyiwa A.; Malathi, M; Paswan, Dayanand

doi:10.1016/j.heliyon.2020.e03582

Cited by 75 publications

(59 citation statements)

References 28 publications

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“…This attempt is a vital one that can continue to allow researchers in waste to wealth area to save economical and viable materials in terms of biomass and coal fines from being loss. An attempt made to develop a hybrid fuel briquette from a lean-grade coal and torrefied biomass using organic binding agents by Adeleke et al 131,134 was successful with torrefied biomass replacing up to 10% of the whole briquette weight in the study. The briquette produced was mechanically strong.…”

Section: Future Workmentioning

confidence: 96%

Essential basics on biomass torrefaction, densification and utilization

et al. 2020

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Summary Torrefaction and densification are crucial steps in upgrading biomass as feedstock for energy generation and metallurgical applications. This paper attempts to discuss essential basics on biomass torrefaction and densification, which can propel developing nation to take full advantage of them. The most promising clean energy sources that have found applications in various areas are biomass materials, that is, both the lignocellulosic and non‐lignocellulosic. However, high moisture contents, low energy density, hydrophilic nature, poor storage and handling properties are the major drawbacks limiting its usefulness. Therefore, torrefaction as one of the major thermal pre‐treatment processes to upgrade biomass in terms of improved energy density, hydrophobic, moisture content and grindability has been discussed. The influence of temperature, residence time, particle sizes and gas flow rates on the properties of torrefied biomass has also been discussed. The advantages and disadvantages of various torrefaction technologies have also been highlighted. The possible areas of application of torrefied biomass especially densification into pellets and briquettes alongside the equipment required for it have been reviewed in this paper. The torrefied biomass can be deployed in the metallurgical industries as reducing agent in the development of sponge iron from iron ores of various grade including lean ones. The information gathered in this paper from peer‐reviewed articles will reduce the burden of seeking to understand the preliminaries of torrefaction process and its importance.

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Section: Future Workmentioning

confidence: 96%

Essential basics on biomass torrefaction, densification and utilization

et al. 2020

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“…Carbon dioxide is also a warm gas, and its formation leads to the warming up of the atmosphere that leads to global warming. The effects of global warming include, thinning away of the ice in the cold regions of the earth, climate change issues like excessive rainfall and excessive heats ( Poudel et al., 2011 ; Gaballah et al., 2015 , Odusote et al., 2019 ; Adeleke et al., 2019a , b , c ; 2020a , b ). Droughts are more prolonged in the southwest region and there is a global sea level rise.…”

Section: Introductionmentioning

confidence: 99%

“…(2015a , b ) stated that one of the advantages of biomass, as a reliable energy source is that its production can be domesticated as such, the fluctuations in price of commodities in the international market does not affect it. The various energy products that can be derived from biomass include solid fuel, bioethanol, biogas and biodiesel ( Adeleke et al., 2020a , b ; Ikubanni et al., 2021 ). Biomass is also a reliable raw material for the production of biochemical, biopolymer poly-hydroxyalkanoates, biopolymer and biocatalysts ( Liu et al., 2021 ).…”

Section: Introductionmentioning

confidence: 99%

Sustainability of multifaceted usage of biomass: A review

Adeleke

Ikubanni

Orhadahwe

et al. 2021

Heliyon

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The paper focuses on collection of information on recent multifaceted usage of biomass materials with critical examination on its sustainability. The use of biomass is becoming popular, with wide global acceptance as it is considered as green technology. The use of biomass products across industrial parallels, the material combination and production processes were elucidated in this paper. Biomass materials are seen as affordable alternative to conventional materials for domestic and industrial applications. The multifaceted use of biomass, which includes, energy generation, metallurgical applications, construction purposes, reinforcement in metal matrix composite, microelectromechanical system, biochemical and traditional medicine were discussed. This underscores the need to develop a sustainable plan to meet with its diverse usage to be beyond laboratory efforts. This paper examined whether the availability of biomass can sustain its multifaceted usage or not. It also examined the modalities to ensure sustainable use of biomass. Different policies were highlighted and discussed in line with continuous multifaceted use of biomass.

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“…The role of kinetics modeling is vitally critical to understanding the underlying phenomena and mechanisms that govern thermal processes, making it a complementary tool to experimental analysis. It has been noted that pyrolysis kinetics could produce sub-models that could be coupled to transport phenomena equations to aptly describe thermochemical conversion processes, and also help in the design of efficient reactors 4 , 16 , 17 . To obtain the kinetic data, either model-fitting or iso-conversional techniques could be utilized.…”

Section: Introductionmentioning

confidence: 99%

Kinetics modeling, thermodynamics and thermal performance assessments of pyrolytic decomposition of Moringa oleifera husk and Delonix regia pod

Balogun

Adeleke

Ikubanni

et al. 2021

Sci Rep

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A non-isothermal decomposition of Moringa oleifera husk and Delonix regia seed pod was carried out in an N2 pyrolytic condition with the primary objective of undertaking the kinetics modeling, thermodynamics and thermal performance analyses of the identified samples. Three different isoconversional models, namely, differential Friedman, Flynn–Wall–Ozawa, and Starink techniques were utilized for the deduction of the kinetics data. The thermodynamic parameters were deduced from the kinetic data based on a first-order chemical reaction model. In the kinetics study, a strong correlation (R2 > 0.9) was observed throughout the conversion range for all the kinetic models. The activation energy profiles showed two distinctive regions. In the first region, the average activation energy values were relatively higher—a typical example is in the Flynn–Wall–Ozawa technique—MH (199 kJ/mol) and RP (194 kJ/mol), while in the second region, MH (292 kJ/mol) and RP (234 kJ/mol). It was also demonstrated that the thermal process for the samples experienced endothermic reactions thought the conversion range. In summary, both the kinetic and thermodynamic parameters vary significantly with conversion—underscoring the complexity associated with the thermal conversion of lignocellulosic biomass samples.

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The ignitability, fuel ratio and ash fusion temperatures of torrefied woody biomass

Cited by 75 publications

References 28 publications

Essential basics on biomass torrefaction, densification and utilization

Essential basics on biomass torrefaction, densification and utilization

Sustainability of multifaceted usage of biomass: A review

Kinetics modeling, thermodynamics and thermal performance assessments of pyrolytic decomposition of Moringa oleifera husk and Delonix regia pod

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