Objective: The study aims to propose a business model for converting industrial waste, such as scrap tires, into clean renewable energy through pyrolysis technology, addressing environmental challenges and promoting sustainable energy practices in developing countries.

Methods: The research employs an analytical approach, incorporating experimental data from Vietnam's waste tire pyrolysis industry. It includes case studies, product testing, and real-world business results to evaluate the feasibility of the proposed model.

Results: The study demonstrates the effectiveness of pyrolysis technology in converting waste tires into renewable energy products, such as FO-R oil, carbon black, and steel. The business model offers economic and environmental benefits, such as reducing industrial waste, minimizing greenhouse gas emissions, and creating sustainable business opportunities.

Conclusions: The proposed business model presents a viable solution for recycling industrial waste into renewable energy. Governments and authorities in developing and developed countries are encouraged to implement supportive policies and provide funding channels to promote clean energy production, benefiting society, investors, and the environment.

Batista, R. R., & Gomes, M. M. (2021). Effects of chemical composition and pyrolysis process variables on biochar yields: correlation and principal component analysis. Floresta e Ambiente, 28, e20210007.

Bekhet, H. A., & Harun, N. H. (2016). Role of non-renewable and renewable energy for sustainable electricity generation in Malaysia. International Journal of Environmental and Ecological Engineering, 10(9), 907-916.

Bradu, P., Biswas, A., Nair, C., Sreevalsakumar, S., Patil, M., Kannampuzha, S., & Gopalakrishnan, A. V. (2023). Recent advances in green technology and Industrial Revolution 4.0 for a sustainable future. Environmental Science and Pollution Research, 30(60), 124488-124519.

https://masdar.ae/en/masdar-clean- energy/technologies/waste-to-energy

https://ramboll.com/services-and- sectors/energy/waste-to-energy

Kweku, D. W., Bismark, O., Maxwell, A., Desmond, K. A., Danso, K. B., Oti-Mensah, E. A., ... & Adormaa, B. B. (2018). Greenhouse effect: greenhouse gases and their impact on global warming. Journal of Scientific research and reports, 17(6), 1-9.

Letcher, T. M. (2022). Global warming, greenhouse gases, renewable energy, and storing energy. In Storing Energy (pp. 3-12). Elsevier.

Liu, Q., Wang, S., Zhang, W., Zhan, D., & Li, J. (2018). Does foreign direct investment affect environmental pollution in China's cities? A spatial econometric perspective. Science of the total environment, 613, 521-529.

Nahian, M.R, and Islam M.N (2012), Improvement of Waste Tire Pyrolysis Oil and Performance Test with Diesel in CI Engine, Journal of Renewable Energy, Vol 2016.

Panwar, N. L., Kaushik, S. C., & Kothari, S. (2011). Role of renewable energy sources in environmental protection: A review. Renewable and sustainable energy reviews, 15(3), 1513-1524.

Pratiwi, S., & Juerges, N. (2020). Review of the impact of renewable energy development on the environment and nature conservation in Southeast Asia. Energy, Ecology and Environment, 5(4), 221-239.

Rombaldo, C. F. S., Lisbôa, A. C. L., Méndez, M. O. A., & Coutinho, A. D. R. (2008). Effect of operating conditions on scrap tire pyrolysis. Materials Research, 11, 359-363.

Thanh, N. C., Dat, N. D., Chuong, N. D. A., & Huy, D. T. N. (2020). A Business Model for Producing Clean Energy in Developing Countries. WSEAS Transactions on Business and Economics, 17, 75-84.