Experiments and modeling of single plastic particle conversion in suspension

Mohammadhadi Nakhaei; Hao Wu; Damien Grévain; Lars Skaarup Jensen; Peter Glarborg; Sønnik Clausen; Kim Dam–Johansen

doi:10.1016/j.fuproc.2018.05.003

Experiments and modeling of single plastic particle conversion in suspension

Mohammadhadi Nakhaei^*, Hao Wu, Damien Grévain, Lars Skaarup Jensen, Peter Glarborg, Sønnik Clausen, Kim Dam–Johansen

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

Abstract

Conversion of single high density polyethylene (PE) particles has been studied by experiments and modeling. The experiments were carried out in a single particle combustor for five different shapes and masses of particles at temperature conditions of 900 and 1100°C. Each experiment was recorded using a camera. For selected experiments, the center and surface temperatures of the particles were measured using a thermocouple and an IR camera, respectively. During each experiment, the polyethylene particles went through melting, deformation,
and decomposition. After the start of decomposition, the surface temperature became almost constant within the range of 480–550°C. The total conversion times of polyethylene particles were mainly influenced by the reactor temperature and particle mass, and the effect of particle shape was less significant. A non–isothermal 1D model was established and validated against the experiments as well as literature data. Furthermore, a simplified isothermal model appropriate for CFD applications was developed, in order to model the combustion of plastic
particles in cement calciners. By comparing predictions with the isothermal and the non–isothermal models under typical calciner conditions, it is shown that the accuracy in prediction of the total conversion times of thermoplastic particles is within±30%, for particles lighter than 1000 mg.

Original language	English
Journal	Fuel Processing Technology
Volume	178
Pages (from-to)	213-225
ISSN	0378-3820
DOIs	https://doi.org/10.1016/j.fuproc.2018.05.003
Publication status	Published - 2018

Cite this

Nakhaei, M., Wu, H., Grévain, D., Jensen, L. S., Glarborg, P., Clausen, S., & Dam–Johansen, K. (2018). Experiments and modeling of single plastic particle conversion in suspension. Fuel Processing Technology, 178, 213-225. https://doi.org/10.1016/j.fuproc.2018.05.003

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title = "Experiments and modeling of single plastic particle conversion in suspension",

abstract = "Conversion of single high density polyethylene (PE) particles has been studied by experiments and modeling. The experiments were carried out in a single particle combustor for five different shapes and masses of particles at temperature conditions of 900 and 1100°C. Each experiment was recorded using a camera. For selected experiments, the center and surface temperatures of the particles were measured using a thermocouple and an IR camera, respectively. During each experiment, the polyethylene particles went through melting, deformation,and decomposition. After the start of decomposition, the surface temperature became almost constant within the range of 480–550°C. The total conversion times of polyethylene particles were mainly influenced by the reactor temperature and particle mass, and the effect of particle shape was less significant. A non–isothermal 1D model was established and validated against the experiments as well as literature data. Furthermore, a simplified isothermal model appropriate for CFD applications was developed, in order to model the combustion of plasticparticles in cement calciners. By comparing predictions with the isothermal and the non–isothermal models under typical calciner conditions, it is shown that the accuracy in prediction of the total conversion times of thermoplastic particles is within±30%, for particles lighter than 1000 mg.",

author = "Mohammadhadi Nakhaei and Hao Wu and Damien Gr{\'e}vain and Jensen, {Lars Skaarup} and Peter Glarborg and S{\o}nnik Clausen and Kim Dam–Johansen",

year = "2018",

doi = "10.1016/j.fuproc.2018.05.003",

language = "English",

volume = "178",

pages = "213--225",

journal = "Fuel Processing Technology",

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TY - JOUR

T1 - Experiments and modeling of single plastic particle conversion in suspension

AU - Nakhaei, Mohammadhadi

AU - Wu, Hao

AU - Grévain, Damien

AU - Jensen, Lars Skaarup

AU - Glarborg, Peter

AU - Clausen, Sønnik

AU - Dam–Johansen, Kim

PY - 2018

Y1 - 2018

N2 - Conversion of single high density polyethylene (PE) particles has been studied by experiments and modeling. The experiments were carried out in a single particle combustor for five different shapes and masses of particles at temperature conditions of 900 and 1100°C. Each experiment was recorded using a camera. For selected experiments, the center and surface temperatures of the particles were measured using a thermocouple and an IR camera, respectively. During each experiment, the polyethylene particles went through melting, deformation,and decomposition. After the start of decomposition, the surface temperature became almost constant within the range of 480–550°C. The total conversion times of polyethylene particles were mainly influenced by the reactor temperature and particle mass, and the effect of particle shape was less significant. A non–isothermal 1D model was established and validated against the experiments as well as literature data. Furthermore, a simplified isothermal model appropriate for CFD applications was developed, in order to model the combustion of plasticparticles in cement calciners. By comparing predictions with the isothermal and the non–isothermal models under typical calciner conditions, it is shown that the accuracy in prediction of the total conversion times of thermoplastic particles is within±30%, for particles lighter than 1000 mg.

AB - Conversion of single high density polyethylene (PE) particles has been studied by experiments and modeling. The experiments were carried out in a single particle combustor for five different shapes and masses of particles at temperature conditions of 900 and 1100°C. Each experiment was recorded using a camera. For selected experiments, the center and surface temperatures of the particles were measured using a thermocouple and an IR camera, respectively. During each experiment, the polyethylene particles went through melting, deformation,and decomposition. After the start of decomposition, the surface temperature became almost constant within the range of 480–550°C. The total conversion times of polyethylene particles were mainly influenced by the reactor temperature and particle mass, and the effect of particle shape was less significant. A non–isothermal 1D model was established and validated against the experiments as well as literature data. Furthermore, a simplified isothermal model appropriate for CFD applications was developed, in order to model the combustion of plasticparticles in cement calciners. By comparing predictions with the isothermal and the non–isothermal models under typical calciner conditions, it is shown that the accuracy in prediction of the total conversion times of thermoplastic particles is within±30%, for particles lighter than 1000 mg.

U2 - 10.1016/j.fuproc.2018.05.003

DO - 10.1016/j.fuproc.2018.05.003

M3 - Journal article

VL - 178

SP - 213

EP - 225

JO - Fuel Processing Technology

JF - Fuel Processing Technology

SN - 0378-3820

ER -

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10.1016/j.fuproc.2018.05.003

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Supplementary material_Experiments and modelling of single plastic particle conversion in suspension
Accepted author manuscript, 11.4 MB
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Manuscript plastic combustion
Accepted author manuscript, 10.3 MB
Embargo ends: 01/06/2020