References

avroen

Омский научный вестник. Серия "Авиационно-ракетное и энергетическое машиностроение"

Omsk Scientific Bulletin. Series Aviation-Rocket and Power Engineering

2588-03732587-764X

Омский государственный технический университет

10.25206/2588-0373-2025-9-3-83-91

WBRLVS

avroen-103

Research Article

АВИАЦИОННАЯ И РАКЕТНО-КОСМИЧЕСКАЯ ТЕХНИКА

AVIATION AND ROCKET-SPACE ENGINEERING

Сравнительный анализ методов индукционного, микроволнового и двухстадийного пиролиза различных полимеров

Comparative analysis of induction, microwave and two-stage pyrolysis methods for various polymers

https://orcid.org/0000-0001-6171-5438

Трушляков

В. И.

Trushlyakov

V. I.

ТРУШЛЯКОВ Валерий Иванович, доктор технических наук, профессор (Россия), профессор кафедры «Авиа- и ракетостроение»

644050, г. Омск, пр. Мира, 11

AuthorID (SCOPUS): 56454317700

ResearcherID: D-7270-2015

TRUSHLYAKOV Valery Ivanovich, Doctor of Technical Sciences, Professor, Professor of the Aircraft and Rocket Building Department

Omsk, Mira Ave., 11, 644050

AuthorID (SCOPUS): 56454317700

ResearcherID: D-7270-2015

vatrushlyakov@yandex.ru

https://orcid.org/0009-0009-9709-1247

Петрук

А. А.

Petruk

A. A.

ПЕТРУК Антон Андреевич, аспирант кафедры «Авиа- и ракетостроение»

644050, г. Омск, пр. Мира, 11

PETRUK Anton Andreevich, Postgraduate оf the Aircraft and Rocket Building Department

Omsk, Mira Ave., 11, 644050

apetruk1800@gmail.com

Омский государственный технический университетРоссияOmsk State Technical UniversityRussian Federation

2025

30092025

938391

2025

Трушляков В.И., Петрук А.А.

Trushlyakov V.I., Petruk A.A.

This work is licensed under a Creative Commons Attribution 4.0 License.

https://ariem.omgtu.ru/jour/article/view/103

Проведён сравнительный анализ существующих методов на основе пиролиза с использованием электромагнитных токов: индукционного, сверхвысокочастотного, а также совместного двухстадийного (индукционного и сверхвысокочастотного). Рассмотрена возможность создания энергетической независимости процесса пиролиза для каждого метода. Оценена эффективность каждого метода на основе введённых критериев эффективности: температурный режим время реакции, выход жидкой, парогазовой и твёрдой фракций, энергозатраты, сложность контроля, универсальность и производительность. Все критерии приведены к безразмерной форме. В качестве базового критерия взяты соответствующие критерии индукционного нагрева.

The article presents a comparative analysis of existing methods based on pyrolysis using electromagnetic currents: induction, ultra-high frequency and two-stage combination (induction and ultra-high frequency). The authors consider the possibility of creating energy independence of the pyrolysis process for each method. Moreover, the effectiveness of each method is evaluated based on the introduced efficiency criteria: a temperature regime, reaction time, the output of liquid, combined-cycle and solid fractions, energy consumption, the complexity of control, versatility and productivity. All criteria are reduced to a dimensionless form. The corresponding criteria of induction heating are considered as the basic one.

пиролизиндукционныйсверхвысокочастотныйдвухстадийныйкритерииэнергетическая независимость.

pyrolysisinductionultra-high frequencytwo-stagecriteriaenergy independence.

References1

Julian A., García-Jiménez [et al.]. Advances in the circularity of end-of-life fibre-reinforced polymers by microwave intensification. Chemical Engineering and Processing — Process Intensification. 2022. Vol. 178. P. 109015. DOI: 10.1016/j.cep.2022.109015.

Giorgini L., Benelli T., Brancolini G. Recycling of carbon fiber reinforced composites waste. Current Opinion in Green and Sustainable Chemistry. 2020. Vol. 26. P. 100368. DOI: 10.1016/j.cogsc.2020.100368.

Karuppannan Gopalraj S., Kärki T. A review on the recycling of waste carbon: fibre recovery, properties and lifecycle analysis. SN Applied Sciences. 2020. Vol. 2. P. 433. DOI: 10.1007/s42452-020-2195-4.

Hu X., Ma D., Zhang G. [et al.]. Microwave-assisted pyrolysis of waste plastics for their resource reuse. Carbon Resources Conversion. 2023. Vol. 6. P. 215–228. DOI: 10.1016/j.crcon.2023.03.002.

Sabogal O., Valin S., Thiery S. [et al.]. Design and thermal characterization of an induction-heated reactor for pyrolysis of solid waste. Chemical Engineering Research and Design. 2021. Vol. 173. P. 206–214. DOI: 10.1016/j.cherd.2021.07.018.

Cuong Duong-Viet, Lai Truong-Phuoc, Lam Nguyen-Dinh [et al.]. Magnetic induction assisted pyrolysis of plastic waste to liquid hydrocarbons on carbon catalyst. Materials Today Catalysis. 2023. Vol. 3. P. 100028. DOI: 10.1016/j.mtcata.2023.

Mariani A., Malucelli G. Insights into induction heating processes for polymeric materials. Energies. 2023. Vol. 16. P. 4535. DOI: 10.3390/en16114535.

Whajah B., Moura N., Blanchard J. [et al.]. Catalytic depolymerization of waste polyolefins by induction heating. Industrial and Engineering Chemistry Research. 2021. Vol. 60. P. 15141–15150. DOI: 10.1021/acs.iecr.1c02674.

Syie Luing W., Armenise S., Nyakuma B. [et al.]. Catalytic pyrolysis of plastics over maghemite-impregnated mesocellular foam using induction heating. Chemical Engineering Transactions. 2022. Vol. 97. P. 25–30. DOI: 10.3303/CET2297005.

Frisa-Rubio A., González-Niño C., Royo P. [et al.]. Chemical recycling of plastics assisted by microwave multifrequency heating. Cleaner Engineering and Technology. 2021. Vol. 5. P. 100297. DOI: 10.1016/j.clet.2021.100297.

Zhou N., Dai L., Lyu Y. [et al.]. Catalytic pyrolysis of plastic wastes in a continuous microwave assisted pyrolysis system. Chemical Engineering Journal. 2021. Vol. 418. P. 129412. DOI: 10.1016/j.cej.2021.129412.

Betancourth Mendoza J. D. Evaluation of manufacturing processes, materials, and energy efficiency in the Italian Eyewear Industry. Universitat Politècnica de Catalunya, 2024. 50 р.

Jeon S., Kim J., Yang D. Design of large-scale microwave cavity for uniform and efficient plastic heating. Polymers. 2022. Vol. 14, Issue 3. P. 541. DOI: 10.3390/polym14030541.

Lee Y. C., Hwang C. C., Tsai Y. H. [et al.]. Development and pasteurization of in-packaged ready-to-eat rice products prepared with novel microwave-assisted induction heating (MAIH) technology. Applied Food Research. 2025. Vol. 5, Issue 1. P. 100697. DOI: 10.1016/j.afres.2025.100697.

Lee Y. C., Hwang C. C., Huang Y. T. Application of novel microwave-assisted induction heating technology for extending the shelf life of ready-to-eat rice through microbial, physical, and chemical quality preservation. Innovative Food Science and Emerging Technologies. 2024. Vol. 93. P. 103640. DOI: 10.1016/j.ifset.2024.103640.

Lee Y. C., Tsai Y. H., Hwang C. C. [et al.]. Evaluating the effect of an emerging microwave-assisted induction heating on the quality and shelf life of pre-packaged Pacific white shrimp Litopenaeus vannamei stored at 4 °C in Taiwan. Food Control. 2022. Vol. 133. P. 108509. DOI: 10.1016/j.foodcont.2021.108509.

Tsai Y. H., Hwang C. C., Lin C. S. [et al.]. Comparison of microwave-assisted induction heating system (MAIH) and individual heating methods on the quality of pre-packaged white shrimp. Innovative Food Science and Emerging Technologies. 2021. Vol. 73. P. 102787. DOI: 10.1016/j.ifset.2021.102787.

The authors declare that there are no conflicts of interest present.