Technical and Economic Analysis of a Novel Integrated Energy System with Waste Tire Pyrolysis and Biogas DOI Open Access
Cheng Xin, Jun Liu,

Tianqiong Chen

et al.

Processes, Journal Year: 2025, Volume and Issue: 13(2), P. 415 - 415

Published: Feb. 5, 2025

To reduce dependence on fossil fuels, cope with the growing energy demand, and greenhouse gas emissions, this paper innovatively designs a novel integrated system integrating anaerobic digestion of animal manure, fuel cell technology, turbine, tire pyrolysis. The maximizes potential biogas while synergistically treating waste tires, improving management’s flexibility, efficiency, economic viability through multiple outputs such as electricity by-products, subsystem synergies, equipment sharing, economies scale. Thermodynamic performance feasibility are analyzed using Aspen Plus V14 simulation modeling, ensuring system’s technical viability. In study, model is established, techno-economic benefits analyzed. results show that net electric power output 444.79 kW. Combined contribution pyrolysis products, total efficiency reaches 70.88%. only 4.79 years, initial investment can be recovered, in its 25-year service life, has realized profit 2,939,130 USD. realizes quality matching between different thermal processes indirect collaborative treatment solid wastes, improves conversion energy, co-treats reduces environmental pollution.

Language: Английский

Technical and Economic Analysis of a Novel Integrated Energy System with Waste Tire Pyrolysis and Biogas DOI Open Access
Cheng Xin, Jun Liu,

Tianqiong Chen

et al.

Processes, Journal Year: 2025, Volume and Issue: 13(2), P. 415 - 415

Published: Feb. 5, 2025

To reduce dependence on fossil fuels, cope with the growing energy demand, and greenhouse gas emissions, this paper innovatively designs a novel integrated system integrating anaerobic digestion of animal manure, fuel cell technology, turbine, tire pyrolysis. The maximizes potential biogas while synergistically treating waste tires, improving management’s flexibility, efficiency, economic viability through multiple outputs such as electricity by-products, subsystem synergies, equipment sharing, economies scale. Thermodynamic performance feasibility are analyzed using Aspen Plus V14 simulation modeling, ensuring system’s technical viability. In study, model is established, techno-economic benefits analyzed. results show that net electric power output 444.79 kW. Combined contribution pyrolysis products, total efficiency reaches 70.88%. only 4.79 years, initial investment can be recovered, in its 25-year service life, has realized profit 2,939,130 USD. realizes quality matching between different thermal processes indirect collaborative treatment solid wastes, improves conversion energy, co-treats reduces environmental pollution.

Language: Английский

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