Kinetic study on the pyrolysis of low-density polyethylene (LDPE) waste using kaolin as catalyst

Erawati, Emi; Hamid, .; Martenda, Danik

doi:10.1088/1757-899x/778/1/012071

Cited by 7 publications

(3 citation statements)

References 17 publications

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“…This temperature range was used in order to separate fractions that could possibly include aviation kerosene, which could possibly be part of the pyrolyzed oil. The factors were chosen according to the works developed in the literature (Erawati et al 2020). Through CG-MS Agilent 7820 column C18 it was possible to identify the closest proximity of the oil by comparing the peak areas with diesel, gasoline and aviation kerosene standards.…”

Section: Methodsmentioning

confidence: 99%

Modeling and optimization of the pyrolysis oil production process from polypropylene for the production of aviation kerosene

Santos

Santos²,

Quintão³

et al. 2022

Clean Techn Environ Policy

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One of the greatest challenges in the world is in the nal disposal of plastics in order to reduce the effect of its polluting potential. Thus, the application of pyrolysis processes in generating products of interest such as fuel oils can be part of the solution. In addition to reducing greenhouse gas emissions to the atmosphere, oil can enter the supply chain after the cracking process in petrochemical industries. In this context, this work used statistical modeling of the response surface linked to the Normal Boundary Intersection algorithm, aiming at a higher yield of oil production and major selectivity of recycled polypropylene pyrolysis. From the analysis of the mechanisms proposed in the literature with the modeling and optimization in this work, it was possible, from a kaolin mass of 9.12 g and a heating ramp of 19.37°C/min, to obtain higher percentages of aviation kerosene as well as a satisfactory performance.

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Section: Methodsmentioning

confidence: 99%

Modeling and optimization of the pyrolysis oil production process from polypropylene for the production of aviation kerosene

Santos

Santos²,

Quintão³

et al. 2022

Clean Techn Environ Policy

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“…They found that the yield of aromatic hydrocarbons increases with the reuse of the catalyst, which is associated with an increase in particle size [ 16 ]. The optimal size of kaolin particles was investigated in the work of Erawati et al, where it was established as 7.5 × 6.5 cm [ 19 ].…”

Section: Kaolin Group Catalytic Activitymentioning

confidence: 99%

“…In summarizing, the highest liquid yields described in the articles concerned with kaolin catalysts for different plastics are 78.7 wt% for HDPE over nitric acid-treated kaolin [ 14 ], 99.82 wt% for LDPE on neat kaolin powder [ 19 ], 92 wt% for PP on sulfuric acid-treated kaolin [ 25 ], and 96.37 wt% for PS over pristine kaolin [ 29 ]. Quite expectably, the most efficient catalysts were obtained using acidic treatment, which led to the generation of a sufficient number of acidic sites.…”

Section: Kaolin Group Catalytic Activitymentioning

confidence: 99%

Thermocatalytic Conversion of Plastics into Liquid Fuels over Clays

2022

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Recycling polymer waste is a great challenge in the context of the growing use of plastics. Given the non-renewability of fossil fuels, the task of processing plastic waste into liquid fuels seems to be a promising one. Thermocatalytic conversion is one of the methods that allows obtaining liquid products of the required hydrocarbon range. Clays and clay minerals can be distinguished among possible environmentally friendly, cheap, and common catalysts. The moderate acidity and the presence of both Lewis and Brønsted acid sites on the surface of clays favor heavier hydrocarbons in liquid products of reactions occurring in their pores. Liquids produced with the use of clays are often reported as being in the gasoline and diesel range. In this review, the comprehensive information on the thermocatalytic conversion of plastics over clays obtained during the last two decades was summarized. The main experimental parameters for catalytic conversion of plastics according to the articles’ analysis, were the reaction temperature, the acidity of modified catalysts, and the catalyst-to-plastic ratio. The best clay catalysts observed were the following: bentonite/spent fluid cracking catalyst for high-density polyethylene (HDPE); acid-restructured montmorillonite for medium-density polyethylene (MDPE); neat kaolin powder for low-density polyethylene (LDPE); Ni/acid-washed bentonite clay for polypropylene (PP); neat kaolin for polystyrene (PS); Fe-restructured natural clay for a mixture of polyethylene, PP, PS, polyvinyl chloride (PVC), and polyethylene terephthalate (PET). The main problem in using natural clays and clay minerals as catalysts is their heterogeneous composition, which can vary even within the same deposit. The serpentine group is of interest in studying its catalytic properties as fairly common clay minerals.

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Investigation of waste LDPE with Pongamia pinnata seed for sustainable resource recovery: Thermodynamics, Kinetics and artificial neural network modeling for co-pyrolysis potential

Mohan,

Pandey,

Sahoo

et al. 2024

Sustainable Chemistry for the Environment

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Kinetic study on the pyrolysis of low-density polyethylene (LDPE) waste using kaolin as catalyst

Cited by 7 publications

References 17 publications

Modeling and optimization of the pyrolysis oil production process from polypropylene for the production of aviation kerosene

Modeling and optimization of the pyrolysis oil production process from polypropylene for the production of aviation kerosene

Thermocatalytic Conversion of Plastics into Liquid Fuels over Clays

Investigation of waste LDPE with Pongamia pinnata seed for sustainable resource recovery: Thermodynamics, Kinetics and artificial neural network modeling for co-pyrolysis potential

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