7273634Waste Plastic Oilhttps://www.gandhi.com.mx/waste-plastic-oil-1230008744609/phttps://gandhi.vtexassets.com/arquivos/ids/6823884/image.jpg?v=638739623627030000328328MXNGandhiInStock/Ebooks/6912141Waste Plastic Oil328328https://www.gandhi.com.mx/waste-plastic-oil-1230008744609/phttps://gandhi.vtexassets.com/arquivos/ids/6823884/image.jpg?v=638739623627030000InStockMXN99999DIEbook20251230008744609_W3siaWQiOiJkNDA4MTZhYi0xNDE0LTRhYTMtYTAwOS01ZTc3NTk5YWVmNjUiLCJsaXN0UHJpY2UiOjMyMCwiZGlzY291bnQiOjAsInNlbGxpbmdQcmljZSI6MzIwLCJpbmNsdWRlc1RheCI6dHJ1ZSwicHJpY2VUeXBlIjoiSXBwIiwiY3VycmVuY3kiOiJNWE4iLCJmcm9tIjoiMjAyNS0wMi0wMVQwNTowMDowMFoiLCJyZWdpb24iOiJNWCIsImlzUHJlb3JkZXIiOmZhbHNlfV0=1230008744609_The increasing demand for industrial innovation and advanced technology is due to the global moderation of society. For several decades, Energy has become a demandable research area all over the world. Demand for alternative sources of energy has been long realized. Cutting-edge science and technology have no value if it doesnt serve the purpose. In this regard, several alternative energy resources have been developed and the search is still going on. Amongst various alternative energy resources, waste plastics-derived liquid fuel was explored by several researchers to reduce the pressure on fossil fuels and at the same time to control the issues pertinent to non-biodegradable plastic wastes. Plastic wastes are not easily flattened. Waste plastic disposal is a giant challenge for the global environment. The world is now moving toward zero-waste technology following a green and safe ambiance. Incineration and landfills are common and most popular ways of decomposing wastes, but incineration of plastic wastes threatens the next pollution such as the emission of CO2 and soil pollution. As plastics are made of polymers they take several years to demolition due to their non-biodegradable nature. It is time to move forward with waste-to-wealth technology. Energy from waste alteration methods plays a favorable role in zero-waste technology ahead.The present book explores the experimental production of liquid hydrocarbons by thermo-catalytic degradation of waste high-density polyethylene using kaolin clay, and sodium bentonite as catalysts at lab scale. The types of liquid fuel have been produced by using mutated catalysts. The experimental results show that mutated kaolin clay and sodium bentonite clay have prominent characteristics in the conversion of waste polymers into useful hydrocarbons. Optimal studies explore that the maximum liquid fuel yield is caused by the mixture of acid-treated catalysts. 61.89 of oil yield has been increased with acid-treated catalysts whereas 38.07 of increased oil yield has been calculated with base-treated catalysts. Without using any catalysts thermal degradation of waste high-density polyethylene is recommended for the production of gaseous products. Maximum gas yield has been calculated without using a catalyst.The liquid fuels produced from the thermo-catalytic waste valorization of high-density polyethylene mainly contain aliphatic compounds. The presence of mutated catalysts greatly supports thermo-catalytic reactions. Finally, the economic analysis of the waste high-density liquid hydrocarbons supports the industrial-scale waste plastic oil production, which will boost both the rural economy and energy security of the country.The fuel properties of the produced liquid samples are similar to that of petroleum products. Therefore they can be used as an engine fuel after fractionation or as a feedstock to petroleum refineries....1230008744609_Ramchandra Chandravansi Institute of Technologylibro_electonico_1230008744609_1230008744609Dr. AwinashInglésMéxicohttps://getbook.kobo.com/koboid-prod-public/7d35feb0-8b1d-4cc5-8176-1ae6a62dcc21-epub-062b402a-c67c-4725-8e80-c1adf6d8d65b.epub2025-02-01T00:00:00+00:00Ramchandra Chandravansi Institute of Technology