Pyrolysis Oil from Scrap Tires as a Source of Fuel Components: Manufacturing, Fractionation, and Characterization

Wądrzyk, Mariusz; Janus, Rafał; Rządzik, Bartłomiej; Lewandowski, Marek; Budzyń, S.

doi:10.1021/acs.energyfuels.0c00265

Cited by 24 publications

(17 citation statements)

References 41 publications

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“…Reports on the fractionation of TPO and acquisition of the mentioned chemicals (BTEX, limonene) are rather scarce in the literature. Most of the studies on distillation are found using lab-scale facilities operated at batch mode and aimed at producing fuel-like streams. ,, In addition, BTEX and limonene production are mainly focused via catalytic pyrolysis. − To the best of the authors’ knowledge, this is the first study showing the continuous fractioning of TPO in a pilot-scale distillation plant using a packed column. The goal of this work is not only to demonstrate the technical feasibility to recover valuable products from TPO by distillation but also to gather key information for future optimization steps, as well as for bringing the process at industrial scales.…”

Section: Introductionmentioning

confidence: 99%

On Fractioning the Tire Pyrolysis Oil in a Pilot-Scale Distillation Plant under Industrially Relevant Conditions

et al. 2023

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Tire pyrolysis oil (TPO) is one of the most interesting products derived from the pyrolysis of end-of-life tires. Among others, it contains valuable chemicals, such as benzene, toluene, ethylbenzene, and xylene (BTEX), as well as limonene. In order to recover these chemicals, a pilot-scale distillation plant has been designed, erected, and operated using TPO derived from an industrial-scale pyrolysis plant. The distillation facility consists of a packed column (20 kg/h) and is within the fifth technological readiness level. This work describes for the first time the fractioning of the TPO in a continuous operational mode under industrially relevant conditions. For this purpose, different reboiler temperatures (250–290 °C) and reflux ratios (up to 2.4) were preliminarily assessed on the yields and properties of the resulting products: light fraction (LF) and heavy fraction (HF). Thus, the distillation plant is capable of producing 27.0–36.7 and 63.3–73.0 wt % of LF and HF, respectively. The highest BTEX concentration in the LF (55.2 wt %) was found using a reboiler temperature of 250 °C and a reflux ratio of 2.4. Contrarily, the highest limonene concentration (4.9 wt %) in the LF was obtained at 290 °C in the reboiler without reflux. In this sense, the lower the reboiler temperature, the higher the BTEX, and the lower the limonene concentration in the LF. The main results herein obtained serve to gain key insights to operate packed distillation columns using complex and promising hydrocarbons as TPO in order to recover valuable products. In addition, this work provides significant information for optimizing the recovery efficiencies of both BTEX and limonene, as well as their potential applications including that for the resulting HF.

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Section: Introductionmentioning

confidence: 99%

On Fractioning the Tire Pyrolysis Oil in a Pilot-Scale Distillation Plant under Industrially Relevant Conditions

et al. 2023

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“…Pyrolysis: Pyrolysis or thermal degradation (up to 800 °C) produces tyre-derived fuel known as tar pyrolysis oil (TPO) that has similar properties to diesel fuel. TPO can be used as heating, power generation, and automobile fuels, or in biorefineries [ 28 ]. The thermal degradation of tyres, however, requires a complex setup, high capital cost, skilled operators, and supplemental fuel to initiate and maintain the incineration process [ 29 ].…”

Section: Rubber—polyisoprenesmentioning

confidence: 99%

Microbial Degradation of Rubber: Actinobacteria

et al. 2021

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Rubber is an essential part of our daily lives with thousands of rubber-based products being made and used. Natural rubber undergoes chemical processes and structural modifications, while synthetic rubber, mainly synthetized from petroleum by-products are difficult to degrade safely and sustainably. The most prominent group of biological rubber degraders are Actinobacteria. Rubber degrading Actinobacteria contain rubber degrading genes or rubber oxygenase known as latex clearing protein (lcp). Rubber is a polymer consisting of isoprene, each containing one double bond. The degradation of rubber first takes place when lcp enzyme cleaves the isoprene double bond, breaking them down into the sole carbon and energy source to be utilized by the bacteria. Actinobacteria grow in diverse environments, and lcp gene containing strains have been detected from various sources including soil, water, human, animal, and plant samples. This review entails the occurrence, physiology, biochemistry, and molecular characteristics of Actinobacteria with respect to its rubber degrading ability, and discusses possible technological applications based on the activity of Actinobacteria for treating rubber waste in a more environmentally responsible manner.

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“…This waste made of natural and synthetic rubber, carbon black, textile material, steel, sulfur, and additives can be thermochemically converted (pyrolyzed), generating tire pyrolysis oils having a comparable calorific value to petroleum . Thermal degradation of waste tires leads to broad and complex chemical composition, dominated by hydrocarbons, classically requesting in-depth characterization. , Interestingly, also PAHs, from the cyclization and aromatization of the thermal degradation product butadiene, and amines as well as thiophenes, from additives and manufacturing accelerators, were found . Prospectively, studying the chemical composition of this alternative feedstock will be of high interest for evolved gas analysis soft photoionization mass spectrometry in the framework of a circular economy, particularly taking into account the vital field of co-pyrolysis together with other feedstocks, such polymers and biomass.…”

Section: Alternative Feedstock Energy Materialsmentioning

confidence: 99%

“…159,160 Interestingly, also PAHs, from the cyclization and aromatization of the thermal degradation product butadiene, and amines as well as thiophenes, from additives and manufacturing accelerators, were found. 161 Prospectively, studying the chemical composition of this alternative feedstock will be of high interest for evolved gas analysis soft photoionization mass spectrometry in the framework of a circular economy, particularly taking into account the vital field of co-pyrolysis together with other feedstocks, such polymers and biomass.…”

Section: ■ Liquid Fossil Petroleum and Distillatesmentioning

confidence: 99%

Review on Evolved Gas Analysis Mass Spectrometry with Soft Photoionization for the Chemical Description of Petroleum, Petroleum-Derived Materials, and Alternative Feedstocks

et al. 2021

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Modern industry strongly relies on the molecular analysis of fossil petroleum and petroleum-derived materials. In the context of a circular economy and carbon neutrality, the chemical description of alternative feedstock materials, such as waste plastic and biomass pyrolysis oils, increases in importance. Moreover, online monitoring of the thermochemical and catalytic conversion processes has gained rising attention. In this framework, evolved gas analysis (EGA) concepts with soft photoionization mass spectrometry (PIMS) were successfully deployed for numerous challenges. On the one hand, photoionization is a highly versatile technique and allows for “soft” ionization of the analyte molecule, preserving the molecular information. On the other hand, multiple evolved gas analysis concepts exist with unique benefits, such as the mass loss information in thermogravimetry coupling, high-throughput in direct inlet probe concepts, or straightforward reactor monitoring, allowing for direct online insights into pyrolytic transformation processes. Hence, this review aims to summarize the recent work in the field of EGA–PIMS. After technical description of the multiple photoionization and thermal analysis concepts, applied studies are summarized, discussed, and evaluated. Besides fossil fuels, studies on alternatives from renewable materials, such as biomass pyrolysis, plastic pyrolysis oils, and recycling processes, are reviewed. Finally, future perspectives on this field are given, highlighting the importance of those soft ionization schemes together with state-of-the-art detection by high-resolution mass spectrometry in the field of energy and fuels research.

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Pyrolysis Oil from Scrap Tires as a Source of Fuel Components: Manufacturing, Fractionation, and Characterization

Cited by 24 publications

References 41 publications

On Fractioning the Tire Pyrolysis Oil in a Pilot-Scale Distillation Plant under Industrially Relevant Conditions

On Fractioning the Tire Pyrolysis Oil in a Pilot-Scale Distillation Plant under Industrially Relevant Conditions

Microbial Degradation of Rubber: Actinobacteria

Review on Evolved Gas Analysis Mass Spectrometry with Soft Photoionization for the Chemical Description of Petroleum, Petroleum-Derived Materials, and Alternative Feedstocks

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