Production of fuel by co-pyrolysis of Makarwal coal and waste polypropylene through a hybrid heating system of convection and microwaves

Hussain, Khadim; Hussain, Zahid; Gulab, Hussain; Mabood, Fazal; Khan, Khalid M.; Perveen, Shahnaz; Khalid, Mohammad Hassan Bin

doi:10.1002/er.3537

Cited by 12 publications

(14 citation statements)

References 40 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…If two or more different materials are pyrolyzed together, the process is referred to as co-pyrolysis, 10 for example, coal and polypropylene have been co-pyrolyzed in the presence of copper which resulted in 72% conversion of raw material and greatly affected the composition of pyrolysis oil. 19 The copyrolysis of waste biomass and polyethylene in the presence of waste iron dust and CaCO 3 has been studied that resulted in a greater yield of pyrolysis oil than the noncatalytic process. 10 The literature reveals that to obtain better fuel and achieve a greater conversion, catalytic pyrolysis and co-pyrolysis of waste materials have proven to be efficient processes.…”

Section: Introductionmentioning

confidence: 99%

Catalytic co‐pyrolysis of waste rubber and waste lubricants with waste copper catalyst into value‐added fuel

Gulab

Malik

Hussain

et al. 2021

Intl J of Energy Research

Self Cite

View full text Add to dashboard Cite

The co-pyrolysis of waste rubber and waste lubricating oil was carried out in a batch steel pyrolyzer where waste copper was employed as a catalyst and the reaction conditions were optimized for achieving maximum oil yield. The waste rubber and lubricant were co-pyrolyzed in different ratios and their optimum ratio was found to be 4:1, respectively in terms of maximum pyrolysis oil conversion. About 44% oil yield and 75.5% total conversion of the reactants were achieved under the reaction conditions of 500 C temperature, 30 minute reaction time, 5.0 wt% of catalyst and heating rate of 0.5 o Cs À1 . The noncatalytic pyrolysis yielded about 37.7% oil with 65.0% total conversion under similar reaction conditions. The catalytically produced oil was found to have a higher calorific value as compared to the non-catalytic oil. The catalytic pyrolysis oil was fractionated in gasoline, kerosene and diesel ranges and their fuel properties were investigated according to the ASTM methods. The results showed that the fuel properties of the oil fractions were comparable with that of corresponding standard fuels. The product oil samples were analyzed by means of Fourier-transform infrared spectroscopy spectroscopy and gas chromatography-mass spectrometry to investigate their chemical composition.It was found that the fraction distilled in the gasoline range had a hydrocarbon distribution in the range of C 6 to C 13 , hydrocarbons identified in the fraction distilled in kerosene range were distributed from C 6 to C 16 and the fraction distilled in diesel range was composed of hydrocarbons distributed in the range of C 11 to C 26 .

show abstract

Section: Introductionmentioning

confidence: 99%

Catalytic co‐pyrolysis of waste rubber and waste lubricants with waste copper catalyst into value‐added fuel

Gulab

Malik

Hussain

et al. 2021

Intl J of Energy Research

Self Cite

View full text Add to dashboard Cite

show abstract

“…The total conversion was obtained up to 72% within 22 min through microwave heating. The gas yield was 0.5% of the total mass with the presence of olefins and oil composed with 47.35% of oxygenated aromatic components in addition to long‐chain ketones, alcohols, and alkenes .…”

Section: Conversion Techniquesmentioning

confidence: 99%

A review on conversion techniques of liquid fuel from waste plastic materials

Mohanraj

Senthilkumar

Chandrasekar

2017

Int. J. Energy Res.

View full text Add to dashboard Cite

Summary The utilization of plastics has increased in packing sectors consistently, which lead indirectly to increased volumes of plastic wastes posing an environmental threat. Several utilization and recycling techniques of waste plastics are being practiced commercially around the world. In this article, recent conversion techniques of fuel oil from waste plastics and its utilization on a compression‐ignition engine are discussed. Recent statistics says most of the plastic wastes are generated from packing industries that contains polyethylene, polypropylene. In this connection, conversion techniques of polyethylene and polypropylene practiced frequently by researchers include catalytic processing, thermal degradation, and co‐processing. The effect of various parameters like catalysts, reaction temperature, and reaction time of the aforementioned conversion techniques are discussed in this review. Also, few research works about the utilization of waste plastic oil with a compression‐ignition engine along with engine performance and emissions in various blends of diesel with plastic oil are highlighted here. Copyright © 2017 John Wiley & Sons, Ltd.

show abstract

“…3 Innovative technologies such as pyrolysis and gasification have been proposed as a means of utilizing plastic wastes for the production of fuel and value-added chemicals. [4][5][6][7][8][9][10] Both the pyrolysis and gasification processes employ thermal energy to convert waste plastic materials to liquid fuel and hydrogen-rich syngas without combustion. 3,5 The amount of gasifying agent (oxygen or steam) during the gasification process is often controlled.…”

Section: Introductionmentioning

confidence: 99%

“…Rather than promoting the policy of outright banning waste plastics, researchers have agitated for sustainable utilization of waste plastics for the production of green fuel and chemicals 3 . Innovative technologies such as pyrolysis and gasification have been proposed as a means of utilizing plastic wastes for the production of fuel and value‐added chemicals 4‐10 . Both the pyrolysis and gasification processes employ thermal energy to convert waste plastic materials to liquid fuel and hydrogen‐rich syngas without combustion 3,5 .…”

Section: Introductionmentioning

confidence: 99%

Modeling the prediction of hydrogen production by co‐gasification of plastic and rubber wastes using machine learning algorithms

et al. 2021

View full text Add to dashboard Cite

This study aimed to investigate the application of radial basis function (RBF) and multilayer perceptron (MLP) artificial neural networks for modeling hydrogen production by co-gasification of rubber and plastic wastes. Both the RBF and MLP neural networks were configured by determining the besthidden neurons that could offer optimized performance. Based on the besthidden neurons, a model architecture of 4-16-1, 4-20-1, 4-17-1, and 4-3-1 was obtained for RBF (with standard activation function), RBF (with ordinary activation function), one-layer MLP, and two-layer MLP, respectively, indicating the number of input nodes, the hidden neurons, and the output nodes. The predicted hydrogen production from the co-gasification closely agrees with the observed values. The 1-layer MLP with R 2 of .990 displayed the best performance with all the input parameters having a significant influence on 9 the model output. The neural network algorithm obtained in this study could be implemented in the eventuality of making a vital decision in the process operation of the co-gasification process for hydrogen production.

show abstract

Production of fuel by co-pyrolysis of Makarwal coal and waste polypropylene through a hybrid heating system of convection and microwaves

Cited by 12 publications

References 40 publications

Catalytic co‐pyrolysis of waste rubber and waste lubricants with waste copper catalyst into value‐added fuel

Catalytic co‐pyrolysis of waste rubber and waste lubricants with waste copper catalyst into value‐added fuel

A review on conversion techniques of liquid fuel from waste plastic materials

Modeling the prediction of hydrogen production by co‐gasification of plastic and rubber wastes using machine learning algorithms

Contact Info

Product

Resources

About