High Temperature Electrolysis in Large-Scale Hydrogen Production (K).
- 1st ed.
- 1 online resource (95 pages)
- Energy Science, Engineering and Technology .
- Energy Science, Engineering and Technology .
Intro -- HIGH TEMPERATURE ELECTROLYSIS IN LARGE-SCALE HYDROGEN PRODUCTION -- HIGH TEMPERATURE ELECTROLYSIS IN LARGE-SCALE HYDROGEN PRODUCTION -- CONTENTS -- PREFACE -- Chapter 1 1. INTRODUCTION -- Chapter 2 2. PRINCIPAL CONSIDERATIONS FOR HTE -- 2.1. BASIC PRINCIPLE AND MAIN COMPONENTS -- 2.2. EFFICIENCY ANALYSIS OF HTE -- 2.2.1. Thermodynamic Efficiency -- 2.2.1.1. Power Cycle Efficiency (ηel) -- 2.2.1.2. Electrolysis Efficiency (ηes) -- 2.2.1.3. Thermal Efficiency (ηth) -- 2.2.1.4. Quantitative Analysis of the ηel, ηes and ηth Effects -- 2.2.1.5. Calculations of the ηoverall -- 2.2.2. Overpotential Energy Loss -- Chapter 3 3. CHALLENGE OF HTE TECHNOLOGY DEVELOPMENT -- 3.1. SOEC DEVELOPMENT -- 3.1.1. Cell Sealing -- 3.1.2. Interconnect -- 3.1.3. Electrolyte Performance -- 3.1.4. Anode Material -- 3.1.5. Cathode Material -- 3.1.6. Modular Design -- 3.1.7. System Management -- 3.1.8. Preliminary Economic Analysis of HTE -- 3.2. COUPLING HTE WITH HIGH TEMPERATURE RESOURCE -- 3.2.1. Nuclear Energy -- 3.2.1.1. Coupling Pattern of HTE with HTGR -- 3.2.1.2. Intermediate Heat Exchanger (IHE) -- 3.2.2.2. Nuclear Plant/Hydrogen Plant Safety -- 3.2.2. Renewable Energy -- 3.2.2.1. Geothermal Energy -- 3.2.2.2. Solar Energy and Wind Power -- Chapter 4 4. HISTORY OF HTE STUDIES -- Chapter 5 5. HTE DEVELOPMENT AT INET IN CHINA -- 5.1. HTE DEVELOPMENT SCHEDULE OF INET -- 5.2. R& -- D ON HTE -- Chapter 6 6. CONCLUSION AND DISCUSSIONS -- REFERENCE -- INDEX -- Blank Page.