| EXECUTIVE SUMMARY |
| INTRODUCTION |
| RESULTS AND DISCUSSION |
| |
Task 1: Modeling a Fossil Hydrogen Energy System with CO2
Sequestration |
| Task 2: Designing an Optimized Network |
| Task 3: Case Study of Fossil Hydrogen Production in the
Midwestern US |
| CONCLUSIONS |
| REFERENCES* |
| BIBLIOGRAPHY |
| LIST OF ACRONYMS AND ABBREVIATIONS |
| APPENDICES |
| |
A. Conversion Factors |
| |
| FIGURES |
| |
Figure 1. A simple fossil energy system for production of
hydrogen and electricity with CO2 sequestration. |
| Figure 2. A more complex fossil hydrogen system with CO2
sequestration. |
| Figure 3. Possible method for creating a hydrogen demand map. |
| Figure 4. Hydrogen demand density (kg H2/d/km2) over time at
years 1, 5, 10 and 15, assuming that 25% of new light duty vehicles
use hydrogen, starting in year 1 |
| Figure 5. Chris Yang NHA Figure on length of pipeline versus
city radius. |
| Figure 6. Cost of Local Pipeline Distribution versus pipeline
distance flow rate. |
| Figure 7. Flows for a gaseous hydrogen refueling station. |
| Figure 8. Cost of local hydrogen pipeline distribution
(including 1/2 day storage), as a function of geographic density of
hydrogen vehicles. |
