Waste to energy: An experimental study of utilizing the agricultural residue, MSW, and e-waste available in Bangladesh for pyrolysis conversion

Abstract: The paper aims to study different aspects of liquid fuel production through pyrolysis from agricultural residues, MSW, and e-waste available in Bangladesh. The abundant production of various crops generates massive amounts of residue such as rice straw, wheat straw, rice husk, jute stick, and sugarcane bagasse in Bangladesh have great potential for liquid fuel production for pyrolysis conversion. Bangladesh produces almost 25,000 tons of solid waste per day from urban areas, and Dhaka city alone contributes to… Show more

“…Generally, the production of biochar and bio-oil can be conducted from different waste biomass sources such as almond shell, corn cob, rice husk, sugarcane bagasse, groundnut shell, poplar sawdust, food waste, Crofton weed, citrus peel, coffee husk, palm kernel shell, walnut shell and cassava rhizome ( Cheng et al., 2021 , 2022 ; Egbosiuba et al., 2020a ; Ifa et al., 2020 ; Islam et al., 2021 ; Kalair et al., 2021 ; Morales et al., 2021 ; Nkomo et al., 2021 ; Promraksa and Rakmak, 2020 ; Quillope et al., 2021 ; Rueangsan et al., 2021 ; Saleem, 2022 ; Selvarajoo et al., 2022 ; Soka and Oyekola, 2020b ). The quality of the biochar can be determined by physicochemical parameters such as volatile matter, percentage carbon content, fixed carbon, ash content and higher heating value (HHV).…”

Biochar and bio-oil fuel properties from nickel nanoparticles assisted pyrolysis of cassava peel

“…Generally, the production of biochar and bio-oil can be conducted from different waste biomass sources such as almond shell, corn cob, rice husk, sugarcane bagasse, groundnut shell, poplar sawdust, food waste, Crofton weed, citrus peel, coffee husk, palm kernel shell, walnut shell and cassava rhizome ( Cheng et al., 2021 , 2022 ; Egbosiuba et al., 2020a ; Ifa et al., 2020 ; Islam et al., 2021 ; Kalair et al., 2021 ; Morales et al., 2021 ; Nkomo et al., 2021 ; Promraksa and Rakmak, 2020 ; Quillope et al., 2021 ; Rueangsan et al., 2021 ; Saleem, 2022 ; Selvarajoo et al., 2022 ; Soka and Oyekola, 2020b ). The quality of the biochar can be determined by physicochemical parameters such as volatile matter, percentage carbon content, fixed carbon, ash content and higher heating value (HHV).…”

Biochar and bio-oil fuel properties from nickel nanoparticles assisted pyrolysis of cassava peel

“…However, only 20% of India's total E-waste is collected and recycled. Bangladesh, too, contributes to the generation of a considerable volume of electronic waste on an annual basis [ 87 ]; however, Bangladesh recycles 20% of total E-waste which is more than any other south Asian country, excluding India. Sri Lanka, Nepal, Bhutan, Afghanistan, and Myanmar have no fixed collection or recycling infrastructure, even though they produce a certain amount of E-waste each year.…”

An in-depth analysis and review of management strategies for E-waste in the south Asian region: A way forward towards waste to energy conversion and sustainability

“…At present, the disposal of plastic, aluminum, and rubber is problematic because the burning activity of such waste can pollute the environment, whereas this type of waste can be turned into useful products, e.g., heat, oil, gas, power, and biochar, by applying the process of pyrolysis [117,118]. Researchers have emphasized the use of thermochemical conversion technologies such as pyrolysis, incineration, and gasification techniques for waste-to-energy conversion [119]. Pyrolysis is basically a thermochemical processing technique, through which it is possible to exploit polymers in e-waste in addition to concentrating e-waste metals into a solid residue.…”

Challenges and Opportunities in the Management of Electronic Waste and Its Impact on Human Health and Environment