Equilibrium Modelling and Optimization of the Co-gasification of E-waste and Petcoke

Sameer Khan; Haider Khan; Isam Janajreh

doi:10.1016/j.procs.2024.08.042

Equilibrium Modelling and Optimization of the Co-gasification of E-waste and Petcoke

Sameer Khan
, Haider Khan
, Isam Janajreh

Mechanical & Nuclear Engineering

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

2 Scopus citations

Abstract

Addressing the critical issues of Electronic waste (E-waste) with its low recycling and environmental impacts, this study highlights the necessity for efficient waste management and energy recovery. Leveraging petroleum coke's rich carbon content, co-gasification presents a viable method to transform E-waste into syngas. Using response surface methodology (RSM), the research analyzes various E-waste and petroleum coke blends, focusing on how gasification temperatures and pressures affect cold gas efficiency (CGE). Results highlight that the 25% printed circuit board (PCB) socket blend achieves an optimal CGE of 66.03% at 1,171.27°C and 1.95 bar via RSM and attains 64.10% CGE at 1,150°C and 1 bar as per the equilibrium model, in contrast to the 75% blend's CGE of 49.96% at 1,256°C and 1.57 bar, and 47% at 1,250°C and 1 bar. These findings reveal significant optimization opportunities in co-gasification processes, providing key insights for efficient E-waste handling and syngas generation.

Original language	British English
Pages (from-to)	316-323
Number of pages	8
Journal	Procedia Computer Science
Volume	241
DOIs	https://doi.org/10.1016/j.procs.2024.08.042
State	Published - 2024
Event	19th International Conference on Future Networks and Communications, FNC 2024 / 21st International Conference on Mobile Systems and Pervasive Computing, MobiSPC 2024 / 14th International Conference on Sustainable Energy Information Technology, SEIT 2024 - Huntington, United States Duration: 5 Aug 2024 → 7 Aug 2024

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 12 Responsible Consumption and Production

Keywords

E-waste co-gasification
Gaisficatoon paramaters
Petroleum coke
Printed circuit boards
Response surface methodology

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title = "Equilibrium Modelling and Optimization of the Co-gasification of E-waste and Petcoke",

abstract = "Addressing the critical issues of Electronic waste (E-waste) with its low recycling and environmental impacts, this study highlights the necessity for efficient waste management and energy recovery. Leveraging petroleum coke's rich carbon content, co-gasification presents a viable method to transform E-waste into syngas. Using response surface methodology (RSM), the research analyzes various E-waste and petroleum coke blends, focusing on how gasification temperatures and pressures affect cold gas efficiency (CGE). Results highlight that the 25\% printed circuit board (PCB) socket blend achieves an optimal CGE of 66.03\% at 1,171.27°C and 1.95 bar via RSM and attains 64.10\% CGE at 1,150°C and 1 bar as per the equilibrium model, in contrast to the 75\% blend's CGE of 49.96\% at 1,256°C and 1.57 bar, and 47\% at 1,250°C and 1 bar. These findings reveal significant optimization opportunities in co-gasification processes, providing key insights for efficient E-waste handling and syngas generation.",

keywords = "E-waste co-gasification, Gaisficatoon paramaters, Petroleum coke, Printed circuit boards, Response surface methodology",

author = "Sameer Khan and Haider Khan and Isam Janajreh",

note = "Publisher Copyright: {\textcopyright} 2024 The Authors. Published by Elsevier B.V.; 19th International Conference on Future Networks and Communications, FNC 2024 / 21st International Conference on Mobile Systems and Pervasive Computing, MobiSPC 2024 / 14th International Conference on Sustainable Energy Information Technology, SEIT 2024 ; Conference date: 05-08-2024 Through 07-08-2024",

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doi = "10.1016/j.procs.2024.08.042",

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pages = "316--323",

journal = "Procedia Computer Science",

issn = "1877-0509",

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T1 - Equilibrium Modelling and Optimization of the Co-gasification of E-waste and Petcoke

AU - Khan, Sameer

AU - Khan, Haider

AU - Janajreh, Isam

PY - 2024

Y1 - 2024

N2 - Addressing the critical issues of Electronic waste (E-waste) with its low recycling and environmental impacts, this study highlights the necessity for efficient waste management and energy recovery. Leveraging petroleum coke's rich carbon content, co-gasification presents a viable method to transform E-waste into syngas. Using response surface methodology (RSM), the research analyzes various E-waste and petroleum coke blends, focusing on how gasification temperatures and pressures affect cold gas efficiency (CGE). Results highlight that the 25% printed circuit board (PCB) socket blend achieves an optimal CGE of 66.03% at 1,171.27°C and 1.95 bar via RSM and attains 64.10% CGE at 1,150°C and 1 bar as per the equilibrium model, in contrast to the 75% blend's CGE of 49.96% at 1,256°C and 1.57 bar, and 47% at 1,250°C and 1 bar. These findings reveal significant optimization opportunities in co-gasification processes, providing key insights for efficient E-waste handling and syngas generation.

AB - Addressing the critical issues of Electronic waste (E-waste) with its low recycling and environmental impacts, this study highlights the necessity for efficient waste management and energy recovery. Leveraging petroleum coke's rich carbon content, co-gasification presents a viable method to transform E-waste into syngas. Using response surface methodology (RSM), the research analyzes various E-waste and petroleum coke blends, focusing on how gasification temperatures and pressures affect cold gas efficiency (CGE). Results highlight that the 25% printed circuit board (PCB) socket blend achieves an optimal CGE of 66.03% at 1,171.27°C and 1.95 bar via RSM and attains 64.10% CGE at 1,150°C and 1 bar as per the equilibrium model, in contrast to the 75% blend's CGE of 49.96% at 1,256°C and 1.57 bar, and 47% at 1,250°C and 1 bar. These findings reveal significant optimization opportunities in co-gasification processes, providing key insights for efficient E-waste handling and syngas generation.

KW - E-waste co-gasification

KW - Gaisficatoon paramaters

KW - Petroleum coke

KW - Printed circuit boards

KW - Response surface methodology

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DO - 10.1016/j.procs.2024.08.042

M3 - Conference article

AN - SCOPUS:85204294680

SN - 1877-0509

VL - 241

SP - 316

EP - 323

JO - Procedia Computer Science

JF - Procedia Computer Science

T2 - 19th International Conference on Future Networks and Communications, FNC 2024 / 21st International Conference on Mobile Systems and Pervasive Computing, MobiSPC 2024 / 14th International Conference on Sustainable Energy Information Technology, SEIT 2024

Y2 - 5 August 2024 through 7 August 2024

ER -

Equilibrium Modelling and Optimization of the Co-gasification of E-waste and Petcoke

Abstract

UN SDGs

Keywords

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