Investigation on thermal dechlorination and catalytic pyrolysis in a continuous process for liquid fuel recovery from mixed plastic wastes

Plastics have become an essential part of modern life today. The global production of plastics has gone up to 299 million tonnes in 2013, which has increased enormously in the present years. The utilization of plastics and its final disposal pose tremendous negative significant impacts on the environment. The present study aimed to investigate the thermal and catalytic pyrolysis for the production of fuel oil from the polyethene plastic wastes. The samples collection for both plastic wastes and clay catalyst, sample preparation and pyrolysis experiment for oil production was done in Laroo Division, Gulu Municipality, Northern Uganda Region, Uganda. Catalysts used in the experiment were acid-activated clay mineral and aluminium chlorides on activated carbon. The clay mineral was activated by refluxing it with 6M Sulphuric acid for 3 hours. The experiment was conducted in three different phases: The first phase of the experiment was done without a catalyst (purely thermal pyrolysis). The second phase involves the use of acid-activated clay mineral. The third phase was done using aluminium chlorides on activated carbon. Both phases were done at different heating rates. In purely thermal pyrolysis, 88 mL of oil was obtained at a maximum temperature of 39ºC and heating rates of 12.55ºC /minute and reaction time of 4 hours. Acid activated clay mineral yielded 100 mL of oil with the heating rates of 12.55ºC/minute and reaction time of 3 hours 30 minutes. While aluminium chlorides on activated carbon produced 105 mL of oil at a maximum temperature of 400ºC and heating rates of 15.5ºC /minute and reaction time of 3 hours 10 minutes. From the experimental results, catalytic pyrolysis is more efficient than purely thermal pyrolysis and homogenous catalysis (aluminium chlorides) shows a better result than solid acid catalyst (activated clay minerals) hence saving the energy needed for pyrolysis and making the process more economically feasible.

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A review on catalytic pyrolysis of plastic wastes to high-value products

Energy Conversion and Management ◽

10.1016/j.enconman.2022.115243 ◽

2022 ◽

Vol 254 ◽

pp. 115243

Author(s):

Yujie Peng ◽

Yunpu Wang ◽

Linyao Ke ◽

Leilei Dai ◽

Qiuhao Wu ◽

...

Keyword(s):

Catalytic Pyrolysis ◽

Plastic Wastes

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ChemInform Abstract: Liquid Fuel from Plastic Wastes Using Extrusion-Rotary Kiln Reactors

ChemInform ◽

10.1002/chin.200827269 ◽

2008 ◽

Vol 39 (27) ◽

Author(s):

Sam Behzadi ◽

Mohammed Farid

Keyword(s):

Rotary Kiln ◽

Liquid Fuel ◽

Plastic Wastes

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Thermal and catalytic pyrolysis of Karanja seed to produce liquid fuel

Fuel ◽

10.1016/j.fuel.2013.07.053 ◽

2014 ◽

Vol 115 ◽

pp. 434-442 ◽

Cited By ~ 60

Author(s):

Krushna Prasad Shadangi ◽

Kaustubha Mohanty

Keyword(s):

Liquid Fuel ◽

Catalytic Pyrolysis

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Catalytic pyrolysis of plastic wastes with two different types of catalysts: ZSM-5 zeolite and Red Mud

Applied Catalysis B Environmental ◽

10.1016/j.apcatb.2011.03.030 ◽

2011 ◽

Vol 104 (3-4) ◽

pp. 211-219 ◽

Cited By ~ 171

Author(s):

A. López ◽

I. de Marco ◽

B.M. Caballero ◽

M.F. Laresgoiti ◽

A. Adrados ◽

...

Keyword(s):

Red Mud ◽

Catalytic Pyrolysis ◽

Plastic Wastes ◽

Different Types

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Catalytic pyrolysis of Asbuton into liquid fuel with Zeolite as catalyst

Malaysian Journal of Fundamental and Applied Sciences ◽

10.11113/mjfas.v16n2.1548 ◽

2020 ◽

Vol 16 (2) ◽

pp. 196-200

Author(s):

Nurullafina Saadah ◽

Susianto Susianto ◽

Ali Altway ◽

Yeni Rachmawati

Keyword(s):

Coming Out ◽

Liquid Fuel ◽

Catalytic Pyrolysis ◽

Liquid Product ◽

Optimum Operating ◽

Pyrolysis Process ◽

Optimum Operating Condition ◽

Product Characterization ◽

Oil Density ◽

Cracking Process

Natural Buton Asphalt (Asbuton) is a naturally occurring asphalt that is contained in rock deposit located in Buton Island, Indonesia. Asbuton is mostly used as a mixture of bitumen since it has the potential to be cracked into hydrocarbon and produced as a liquid fuel for energy consumption. The present study aims to investigate the effect of pyrolysis temperature and the mass ratio of the Asbuton with catalyst on the Asbuton conversion. The pyrolysis process is carried out on a batch using vacuum reactor with various temperatures and mass ratios of catalyst to Asbuton. The gas coming out of the process is passed through the condenser, where the condensed gas (liquid product) is collected in the flask, whereas the uncondensed gas (gas product) is collected in a gas holder and the yield is analyzed upon the pyrolysis process completion. The respond parameter of the catalytic pyrolysis are oil flammability, yield, and oil density. The synthesized ZSM-5 catalyst is more effective for the Asbuton bitumen cracking process as opposed to the Natural Zeolite. Furthermore, it is investigated that the most optimum operating condition throughout this experiment was 70.07% and obtained at 350 °C with 9% ZSM-5 catalyst. In terms of product characterization, the liquid product can be ignited during the flame test. From the S.G. and API gravity values, it is suggested that the products belong to crude oil range, and thus, confirming that Asbuton has great potentials to be developed into alternative fuel.

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Effect of Potassium Carbonate Catalyst on Pyrolysis of Milicia excelsa in a Fixed Bed Reactor

FUOYE Journal of Engineering and Technology ◽

10.46792/fuoyejet.v5i2.517 ◽

2020 ◽

Vol 5 (2) ◽

Author(s):

Pious O Okekunle ◽

Oluwatobi S Awani ◽

Daniel O Jimoh

Keyword(s):

Potassium Carbonate ◽

Liquid Fuel ◽

Catalytic Pyrolysis ◽

Fixed Bed ◽

Product Distribution ◽

Fixed Bed Reactor ◽

Catalyst Amount ◽

Different Temperatures ◽

Definite Pattern ◽

Milicia Excelsa

The effect of potassium carbonate catalyst on the products distribution from pyrolysis of Milicia excelsa (Iroko) at various temperatures (400, 500 and 600 oC) was investigated. Milicia excelsa sawdust was obtained from a sawmill in Ogbomoso, South-Western Nigeria and was sundried for five days in order to reduce its moisture content. Catalytic pyrolysis of the sawdust was performed with different amounts of catalyst (10, 20, 30 and 40 wt.%). Non-catalytic pyrolysis was also performed for the same temperatures and the products distributions from both batches were compared. Char yield generally increased with increase in catalyst amount for all the temperatures considered. Tar yield did not follow any definite pattern with increasing amount of catalyst as different trends were obtained for different temperatures. Gas yield generally decreased with increase in catalyst amount in the feed. Char yields from non-catalytic experiments were higher than those obtained from catalytic runs, with the highest value of 68% at 400 oC. Tar yields from catalytic pyrolysis were higher than those from non-catalytic process at 400 oC (biomass/catalyst ratio of 90/10) and at 500 oC (biomass/catalyst ratios of 70/70 and 60/40), the highest yield being 29.47% at 500 oC and biomass/catalyst ratio of 60/40. Gas yields from catalytic pyrolysis were higher than those from non-catalytic runs except at 500 oC (biomass/catalyst ratio of 60/40), the highest being 51.3% at 600 oC (biomass/catalyst ratio of 90/10). By making use of appropriate biomass/catalyst ratio and temperature, the yield of liquid fuel from catalytic pyrolysis of Milicia excelsa can be increased.Keywords— Catalyst, potassium carbonate, pyrolysis, biomass, product distribution

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