Difference between revisions of "User talk:SAF Brazil"

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(DESCRIBE THE DSM)
The tree below shows the relationship between other technologies related to the SAF. It is focus on the enabling technologies to SAF, considering key feedstocks and processes. Starting from our main goal to decarbonize aviation (1ACO), 2SAF plays an important role and can be decomposed in multiple technologies. Focusing on feedstock classification, SAF can be made out of two main technologies including Biofuels (3BFU) making technologies and e-fuels (3FU) making technologies such as 4HEF, 4ATJ, 4FTS and 4PTL. These technologies possess a dependency with specific feedstock technologies and processes such as 5FFO, 5HPS, 5WFO, 5ALG, 5NFW, 5AJC, 5MSW, 5FAR, 5CNG and 5WCO.




[[File:SAF Structure Levels.png |700px|]]
[[File:SAF Structure Levels.png |700px|]]
The DSM below shows the connections of SAF to Level 3, 4 and 5 technologies. These connections will be presented in more detailed in the next section using Object-Process-Model (OPM). 


[[File:SAF DSM Allocation.png |700px|]]
[[File:SAF DSM Allocation.png |700px|]]

Revision as of 22:12, 7 October 2024

Roadmap Creators: Gabriel Ruscalleda, Emilia Ospina Arango and Dawit Dagnaw

Time Stamp: Updated 10 October 2024

Technology Roadmap Sections and Deliverables

Our technology roadmap identifier is shown as:

  • 2BSSAF - Brazil Solution - Sustainable Aviation Fuel

This indicates that we are dealing with a “level 2” roadmap at the product level, where “level 1” would indicate a market level roadmap, "level 2" would indicate our SAF Production and “level 3” or “level 4” would indicate an individual technology roadmap.

Roadmap Overview

Sustainable aviation fuel (SAF) offers a promising solution for reducing the aviation industry’s carbon footprint, but scaling its production to meet global demand presents significant challenges. Brazil is often referred to as the “Saudi Arabia of sustainable fuels” due to its significant potential and advancements in renewable energy.

This roadmap explores the dilemma of SAF scalability, focusing on two critical aspects: availability and affordability. The feedstock supply and production capacity is analyzed within the country, and innovative strategies are proposed to enhance scalability. Additionally, economic competitiveness of SAF will be evaluated and compared to conventional jet fuel, considering factors such as production costs, market incentives, and policy support in Brazil.


The figure below contains graphic representation of the SAF supply chain from the SAF Grand Challenge Roadmap

Figure-2 SAF-roadmap.jpg


SAF can be produced using various technological pathways and feedstock combinations, resulting in different types of SAF. It is important to understand these combinations which allow us to understand any factors directly or indirectly affecting availability and affordability. A general overview of feedstocks and associated pathways is illustrated below


SAF FeedstockPathways.png


Three generations of feedstocks are defined on the IATA SAF Handbook based on their usage chronology, emission reduction potential, sustainability criteria, environmental impact, and availability:

1. First Generation (1G): Includes food-grade fats and oils like canola, palm, and soybean. While technologically mature and commercially scalable, they pose sustainability issues such as competing with food supply and high land usage.

2. Second Generation (2G): Comprises waste fats, oils, and greases (FOGs) like used cooking oil and inedible animal fats. These are more sustainable than 1G due to higher emission reduction and no additional land usage, but are more expensive due to limited supply.

3. Third Generation (3G): Encompasses biological/agricultural wastes and energy crops from degraded land, including municipal solid waste, forestry residues, and algae oils. They offer the most positive environmental impact and cost benefits but require advanced processing technologies.


FeedstockClasification SAF.png 

Design Structure Matrix (DSM) Allocation

The tree below shows the relationship between other technologies related to the SAF. It is focus on the enabling technologies to SAF, considering key feedstocks and processes. Starting from our main goal to decarbonize aviation (1ACO), 2SAF plays an important role and can be decomposed in multiple technologies. Focusing on feedstock classification, SAF can be made out of two main technologies including Biofuels (3BFU) making technologies and e-fuels (3FU) making technologies such as 4HEF, 4ATJ, 4FTS and 4PTL. These technologies possess a dependency with specific feedstock technologies and processes such as 5FFO, 5HPS, 5WFO, 5ALG, 5NFW, 5AJC, 5MSW, 5FAR, 5CNG and 5WCO.


SAF Structure Levels.png

The DSM below shows the connections of SAF to Level 3, 4 and 5 technologies. These connections will be presented in more detailed in the next section using Object-Process-Model (OPM).


SAF DSM Allocation.png

Roadmap Model using OPM

The Object-Process-Model (OPM) of the 3BSSAF - Brazil Solution - Sustainable Aviation Fuel roadmap is presented in the figure with the Object-Process-Language (OPL) below.

Level 1 OPM

SAF OPL level1.png

SAF OPD level1.jpeg

Level 2 OPM

SAF OPL level2.png

SAF OPD level2.jpeg



Figures of Merit

(ADD)


The table below shows a list of FOMs by which charging of electric vehicles can be quantified and compared

Category Figure of Merit Units Description
Competitiveness SAF unit cost [USD/MJ] Market cost of SAF per unit of volume or energy
Competitiveness Cost per reduced ton [USD / tCO2e​] Incremental cost per ton of carbon equivalent reduced vs CAF
Competitiveness Investment potential [USD / tCO2e​] Financing opportunity per potential unit output of technology
Competitiveness Installation cost per unit [USD / Vol] Cost of deploying SAF production infrastructure relative to capability
Efficiency Energy efficiency [%] Energy input to produce SAF vs energy output in SAF
Productivity Feedstock crop yield [Ton / ha] Crop yield in volume produced per unit area
Productivity Feedstock availability [Ton / year] Crop availability in volume produced per year
Productivity SAF conversion yield [%] SAF produced with relation to total refinery biofuel production
Performance Energy density [MJ/Vol] Energy content per unit volume of fuel
Performance Blend ratio of pathway/feedstock [%] Volume SAF relative to total volume of fuel after blend
Performance Fuel consumption [Vol/Time] Fuel consumed per hour of flight to compare SAF vs CAF
Sustainability Carbon savings potential [tCO2e / MJ] Potential reduction in emissions for use of SAF vs CAF as baseline
Sustainability Carbon emissions [tCO2e / MJ] Life-cycle carbon equivalent emissions to generate unit of fuel
Sustainability Emission reduction factor [%] Percentage reduction per equivalent unit of use of SAF


Alignment with Company Strategic Drivers

Positioning of Company vs. Competition

Technical Model

CO2-eq emission model


Fuel consumption model


Feedstock availability model


Technical model integration


Financial Model

List of R&D Projects

Key Publications, Presentations and Patents

Technology Strategy Statement

References

[1] U.S. Department of Energy, U.S. Department of Transportation, U.S. Department of Agriculture, and U.S. Environmental Protection Agency. 2022. SAF Grand Challenge Roadmap: Flight Plan for Sustainable Aviation Fuel. Washington, D.C.: U.S. Department of Energy. https://www.energy.gov/sites/default/files/2022-09/beto-saf-gc-roadmap-report-sept-2022.pdf

[2] Reference 2