Modeling Tools for Planning Sustainable Biomass and Waste Conversion into Energy and Chemicals: Optimization of Technical, Economic, Environmental and Social Key Aspects
Editat de Pietro Bartocci, Francesco Fantozzi, Qing Yang, Yang Haiping, Ondrej Mašek, Yunjun Yan, Zhen Fang, Lucia Rigamontien Limba Engleză Paperback – 29 feb 2024
In addition, sections cover feasibility plans for biorefineries and combined heat and power systems, and the fundamentals and challenges of modeling biomass and waste conversion processes, such as anaerobic digestion, pyrolysis, gasification, combustion, transesterification, fermentation and hydroprocessing. The authors also examine economic and market factors influencing feedstock availability and price and provide tools for environmental and social impact analysis.
- Presents practical tools to design supply plans for waste-to-energy and bioenergy plants, as well as biorefineries, optimizing collection, and logistics within the context of the bioeconomy
- Explores methodologies for the realistic development of bioenergy business plans, environmental impact analysis, plant control and management
- Includes a broad selection of global case studies and practical exercises that illustrate the application of discussed methodologies in biomass and waste conversion chains
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Specificații
ISBN-13: 9780128214435
ISBN-10: 0128214430
Pagini: 600
Ilustrații: Approx. 100 illustrations
Dimensiuni: 191 x 234 mm
Editura: ELSEVIER SCIENCE
ISBN-10: 0128214430
Pagini: 600
Ilustrații: Approx. 100 illustrations
Dimensiuni: 191 x 234 mm
Editura: ELSEVIER SCIENCE
Public țintă
Early career researchers and graduate students in the field of biomass and waste-to-energy systems, as well as biorefining and biomaterialsIndustry practitioners involved in planning, deploying, optimizing and managing biomass and waste-to-energy systems. Instructors in graduate courses or industry training on the topic.
Cuprins
1. Introduction to biomass and waste conversion techniques
2. World bioenergy and WASTE-to-Energy chains and policies
3. The circular economy and the bioeconomy policies
4. Biomass and waste assessment using statistics and GIS systems and Energy crops and microalgae growth modeling
5. Biomass and waste logistics optimization
6. Energy and chemicals demands assessment and modeling
7. Biomass and waste pre-treatment optimization through modeling
8. Anaerobic digestion and fermentation of biomass and waste
9. Thermochemical conversion of biomass and waste: pyrolysis
10. Thermochemical conversion of biomass and waste: combustion
11. Chemical processes modeling (with and without catalysis)
12. Chemical Looping combustion modeling
13. Hydrogen production from biomass and waste
14. Biochemicals and biopolymers production modeling
15. Modeling Biofuels combustion in internal combustion engines and gas turbines
16. Modeling Biofuels and waste derived fuels use in Fuel Cells
17. Modeling polluting emissions formation and reduction
18. Modeling carbon capture, storage and reuse
19. Modeling CHP plants operation
20. Smart grids and microgrids modeling
21. District heating networks design and modeling
22. Bioenergy and waste to energy systems planning and design
23. Biochemicals production plants design and analysis
24. Economic analysis of biomass and waste conversion
25. Life Cycle Assessment (LCA) of biomass and waste conversion chains
26. Social Life Cycle assessment (Social-LCA) of biomass and waste conversion chains
2. World bioenergy and WASTE-to-Energy chains and policies
3. The circular economy and the bioeconomy policies
4. Biomass and waste assessment using statistics and GIS systems and Energy crops and microalgae growth modeling
5. Biomass and waste logistics optimization
6. Energy and chemicals demands assessment and modeling
7. Biomass and waste pre-treatment optimization through modeling
8. Anaerobic digestion and fermentation of biomass and waste
9. Thermochemical conversion of biomass and waste: pyrolysis
10. Thermochemical conversion of biomass and waste: combustion
11. Chemical processes modeling (with and without catalysis)
12. Chemical Looping combustion modeling
13. Hydrogen production from biomass and waste
14. Biochemicals and biopolymers production modeling
15. Modeling Biofuels combustion in internal combustion engines and gas turbines
16. Modeling Biofuels and waste derived fuels use in Fuel Cells
17. Modeling polluting emissions formation and reduction
18. Modeling carbon capture, storage and reuse
19. Modeling CHP plants operation
20. Smart grids and microgrids modeling
21. District heating networks design and modeling
22. Bioenergy and waste to energy systems planning and design
23. Biochemicals production plants design and analysis
24. Economic analysis of biomass and waste conversion
25. Life Cycle Assessment (LCA) of biomass and waste conversion chains
26. Social Life Cycle assessment (Social-LCA) of biomass and waste conversion chains