Syngas production from gasification and
            <scp>co‐gasification</scp>
            of oil palm trunk and frond using a
            <scp>down‐draft</scp>
            gasifier

Umar, Hadiza A.; Sulaiman, Shaharin Anwar; Said, Mohd Ismid Mohd; Güngör, Afşin; Ahmad, Rohiza; Inayat, Muddasser

doi:10.1002/er.6345

Cited by 16 publications

(5 citation statements)

References 46 publications

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“…In the linear programming optimisation model, it was assumed that, the effect of blended feedstocks on syngas yield behaves as a simple linear combination of the individual feedstock in the blends as reported for thermochemical reactions (Edmunds et al, 2018). Similar linear correlation between individual and co-gasified feedstock for syngas yield of palm trunk and oil palm fronds have been reported by Umar et al (2021) with a deviation of 2.8 % between experimental and estimated values.…”

Section: Optimal Syngas Generationmentioning

confidence: 74%

Multi-level framework for optimal operation of gasifier system utilising crop residues from small and medium-scale farms

Osei,

Addo,

Kemausuor

2023

JGhIE

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Lack of techno-economic framework for optimal gasification and the identification of critical parameters for optimal operations is one of the major challenges restricting the gasification of crop residues. This study aims to develop an optimal techno-economic framework for the gasification of crop residues from clustered small/medium-scale farms. The developed model was applied to a case study in Adiembra, a farming community for a 10-kW gasifier engine system. Eight scenarios of individual feedstock and their blends were considered. The results revealed specific fuel consumption ranging from 1.79 – 3.53 kg/kWh. The economic analysis showed marginal profitability except for rice husk and straw which are not profitable. At the current grid electricity price, the minimum level of subsidies required to ensure the financial viability of the feedstocks is within the range of 30 – 70 % of the investment cost based on the various feedstock scenarios considered. The study revealed individual feedstocks with the best technical and economic prospects for optimal gasification to be cocoa pod husk, maize stalk and husk, maize cobs, rice straw and rice husk in the order of best to worst. The use of feedstock blends generally improved the overall syngas characteristics and financial viability. A total number of farms ranging between 107 – 532 are required to be clustered within a radius of 0.74 – 2.12 km with a cluster radius greater than 3.91 km not being financially viable. The fraction of each feedstock type in the blends were optimised with corresponding increase in syngas generation within the range of 9 – 35 % and decrease in the required number of farms within the range of 30 – 57 %. The outcome of the study demonstrates that sustainable gasification of crop residues for minigrid electricity generation requires co-gasification of various residue types, valorisation of by-products and increase in the current feed-in-tariff rate in Ghana.

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Section: Optimal Syngas Generationmentioning

confidence: 74%

Multi-level framework for optimal operation of gasifier system utilising crop residues from small and medium-scale farms

Osei,

Addo,

Kemausuor

2023

JGhIE

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“…The gasification process was carried out with variations in temperature (350, 400, 450, 500, and 550°C), reaction time (10,20,30,40, and 50 minutes), and catalyst addition (10 and 20 wt%). The gasification temperature was regulated and monitored via a K-type thermocouple equipped with a stainless-steel sensor probe and connected to the controller panel.…”

Section: Methodsmentioning

confidence: 99%

Synthetic Gas Production from Fine Coal Gasification Using Low-Cost Catalyst

Andican¹,

Faizal²,

Said³

et al. 2022

J. Ecol. Eng.

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The utilisation of fine coal waste is still limited, even though its availability is very abundant in the mining industry. This study utilises fine coal by converting it into syngas through catalytic gasification. The gasification process was carried out at a temperature range of 350-550°C for 10-50 minutes using natural zeolite as a catalyst. The syngas composition and quality parameters were evaluated through the H 2 /CO ratio, heating value, and gasification efficiency. From the research results, fine coal contained high amounts of carbon and fixed carbon. Temperature is the variable that most influences the gasification process. The addition of zeolite actively increased the CO content in the syngas. The H 2 /CO ratio of syngas >1, the highest HHV and LHV 16.15 and 14.46 MJ/Nm 3 with the highest carbon conversion efficiency value of 88.85%, made fine coal very suitable to be used as raw material for the gasification process to produce environmentally friendly syngas.

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“…The co-gasification of different biomass feedstocks, like oil palm trunk (OPT) and frond (OPF), is considered a reliable means of syngas production. The study found that the optimum blend was 30 OPT/70 OPF, producing the highest gas constituents of CO, H2, and CH4 compared to other blends [152]. The unique thermal decomposition process of pyrolysis technology yields valuable outputs such as bio-oil and biochar, which can be employed for energy generation or as feedstocks for various chemical [153].…”

Section: Technological Innovations Enabling Circular Economy Practicesmentioning

confidence: 99%

Circular Economy Approaches in the Palm Oil Industry: Enhancing Profitability through Waste Reduction and Product Diversification

Siagian,

Wenten,

Khoiruddin

2024

J. Eng. Technol. Sci.

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Today, facing difficult environmental and sustainability questions, the palm oil industry is an important force in global trade and development. As a transformative solution to these problems, this review assesses the implementation of circular economy (CE) strategies. CE principles promote the transformation of waste into value through recycling, upcycling and other low-carbon innovation applications. This review estimates the capability of palm-based biomass, including palm oil mill effluent (POME) and refinery wastes. It evaluates how different technologies such as gasification are used to change these fuel sources into energy fuels and value-added products for industry. It also involves incorporating Industry 4.0 to boost efficiency and waste value creation into the operation. Although the potential of CE in creating an eco-friendly, profitable palm oil industry is apparent, nevertheless it must overcome all kinds and levels of barriers – from economic to technological to social. This review points out for collaborative efforts, technological advancement, and supportive policies to navigate these challenges, advocating for a unified shift towards sustainability and efficiency in the palm oil sector.

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Syngas production from gasification and co‐gasification of oil palm trunk and frond using a down‐draft gasifier

Cited by 16 publications

References 46 publications

Multi-level framework for optimal operation of gasifier system utilising crop residues from small and medium-scale farms

Multi-level framework for optimal operation of gasifier system utilising crop residues from small and medium-scale farms

Synthetic Gas Production from Fine Coal Gasification Using Low-Cost Catalyst

Circular Economy Approaches in the Palm Oil Industry: Enhancing Profitability through Waste Reduction and Product Diversification

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