Single particle flame-combustion studies on solid biomass fuels

Mason, Patrick E.; Darvell, L.I.; Jones, James C. Peyton; Pourkashanian, Mohamed; Williams, Alan

doi:10.1016/j.fuel.2014.11.088

Cited by 80 publications

(62 citation statements)

References 18 publications

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“…Some studies are about the burning of micron‐sized biomass particles. On the basis of the experimental data of single‐particle combustion, Mason et al derived the empirical relationships between combustion characteristics (ignition delay, volatile flame duration, and char burn duration) and properties of biomass particles (size, moisture content, density, and shape). Riaza et al conducted a combustion experiment using coal (300 μm to 1 mm) and biomass particles (610 μm to 3 mm) in a device that was similar to that in Flower and Gibbins .…”

Section: Introductionmentioning

confidence: 99%

An experimental study of single unconventional biomass pellets: Ignition characteristics, combustion processes, and artificial neural network modeling

Lin

Wang

et al. 2020

Int J Energy Res

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Summary This study applied the artificial neural networks (ANNs) model to the thermal data obtained by suspension ignition and combustion experiment of single peanut shells (PS, millimeter scale) pellet under O2/CO2 atmosphere. ANN11 was the best ANN model for predicting the relevant parameters of PS combustion. The coincidence between ANN prediction data and experimental data was over 99%. Two modes of biomass pellet ignition were observed: homogeneous ignition of volatiles and hetero‐homogeneous ignition of volatiles and char simultaneously. The ignition mode was transformed from homogeneous ignition to hetero‐homogeneous ignition when oxygen concentration was 50%. In addition, it was observed that ignition at the bottom emerged first, and then the upper end was ignited, finally generating an envelope flame. This phenomenon occurred when gas flow temperature exceeded 873 K or the oxygen concentration was greater than 50%. The reduction of ignition delay time and internal ignition temperature from 21% to 50% oxygen concentration was more intense than that of 50% to 100% oxygen concentration. Increasing oxygen concentration or temperature resulted in a shorter, brighter, and more stable volatile flame of biomass pellets, which reduced volatile burnout time. Nevertheless, the impact of gas flow rate on biomass combustion was intricate and irregular.

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Section: Introductionmentioning

confidence: 99%

An experimental study of single unconventional biomass pellets: Ignition characteristics, combustion processes, and artificial neural network modeling

Lin

Wang

et al. 2020

Int J Energy Res

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“…The aim is to encourage full biomass conversion as a transitional technology, and replace to RO's with CFD's [7].…”

Section: A Renewable Obligationsmentioning

confidence: 99%

Have Technology Specific Measures for the UK Electricity Market Reform Gone Far Enough?

Baker¹

2015

JOCET

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Abstract-The United Kingdom Government recently published a package of measures which would support investment in low-carbon technologies in the years up to 2020.It has also taken account of the highly uncertain investment conditions relating to the period beyond 2020, which threaten to undermine the 2014 Electricity Market Reform measures and deliver bad value. The CFD scheme under the Energy Act 2013 should provide a stable revenue level which should, in turn, reduce investment risks and financing costs, and so drive innovation and development of low-carbon technologies. The scheme can also cap the support costs for consumers when electricity prices are high. Concerns about the impact of CFD allocation policies on the solar industry can be addressed. This paper indicates that there is a clear benefit in committing to invest in low-carbon generation technologies to 2020, and beyond to the 2030s.The Government should state clearly that it intends to support investments in low-carbon technologies through the 2020s.Index Terms-Renewable obligation, energy solar power, CFD.

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“…A number of experiments were carried out on the combustion of single biomass particles around 1 mm in size. [29][30][31] Single pellets of wood and coal mixtures have not been investigated for sequential co-combustion processes or for burning characteristics at rapid heating rates.…”

Section: Introductionmentioning

confidence: 99%

Combustion Behavior of Single Pellets of Coal–Wood Mixtures in a Hot Gas Flow Field

et al. 2018

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This experimental study explores the burning characteristics of single pellets made of wood and coal mixtures for co-firing. Three types of pellets were prepared with different wood to coal ratios (100:0, 80:20% and 50:50%). Experiments were carried out in a laboratory reactor at rapid heating rates and under oxygen concentrations between 10% and 40%. To investigate their combustion behaviour, a single pellet was suspended on a wire injected into a hot gas stream at 1340 K, and flame and char combustion were recorded through an observation window by means of a high-resolution (4K) camera. The sequential combustion time, volatile flame characteristics and mass reduction rate were obtained over a time profile by carefully controlled particle injection. The results demonstrated that the char combustion time increased significantly compared with the volatile combustion time, which only varied a little, when the pellets contained coal in the mixture. Partially detached flames were also predominantly observed on pure biomass pellets at oxygen concentrations between 21% and 40%. During the homogeneous combustion period, the cross-sectional area of a pellet shrunk by 26.3%-37.5%, depending on the type of pellet.

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Single particle flame-combustion studies on solid biomass fuels

Cited by 80 publications

References 18 publications

An experimental study of single unconventional biomass pellets: Ignition characteristics, combustion processes, and artificial neural network modeling

An experimental study of single unconventional biomass pellets: Ignition characteristics, combustion processes, and artificial neural network modeling

Have Technology Specific Measures for the UK Electricity Market Reform Gone Far Enough?

Combustion Behavior of Single Pellets of Coal–Wood Mixtures in a Hot Gas Flow Field

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