Research on Key Techniques of Hybrid (PV-Wind) Nano Grid for
发布时间:2021-09-05 14:51
The world grapples with the challenges of increasing energy demand for a large and growing population,which is substantially dependent on fossil fuel imports.The second largest global issue is that of climate change.Numerous countries gathered in Paris in 2016 to seek an agreement that addresses climate change.Many countries across Africa,the Asia Pacific region,Latin America,the Caribbean,and the Middle East have suffered a succession of severe energy crises due to inadequate development on the...
【文章来源】:江苏大学江苏省
【文章页数】:151 页
【学位级别】:博士
【文章目录】:
ACKNOWLEDGMENTS
abstract
CHAPTER1 INTRODUCTION
1.1 INTRODUCTION
1.2 PRESENT SCENARIO
1.3 SIGNIFICANCE OF THE STUDY
1.4 LITERATURE REVIEW
1.5 SUMMARY
CHAPTER2 DEVELOPMENT OF A HYBRID(PV-WIND)NANOGRID
2.1 INTRODUCTION
2.2 PROBLEM STATEMENT
2.3 THE PROPOSED ARCHITECTURE OF HYBRID(PV-WIND)NANOGRID
2.3.1 Solar Energy
2.3.2 Wind Energy
2.4 SIMULATION AND RESULTS
2.4.1 Tilted angle for sun radiation
2.4.2 PV Panel
2.4.3 Wind Turbine
2.5 SUMMARY
CHAPTER3 HYBRID(PV-WIND)BASED SCALABLE DC MICROGRID
3.1 INTRODUCTION
3.2 PROBLEM STATEMENT
3.3 THE PROPOSED DC MICROGRID ARCHITECTURE
3.3.1 Hybrid(PV-wind)nanogrid model
3.3.2 Solar Panel
3.3.3 Wind Turbine
3.3.4 DC-DC and AC-DC converters
3.3.5 Bidirectional Flyback Converter
3.3.6 Model village and interconnection of Microgrid Scheme
3.3.7 Power flow analysis for optimal selection of conductor size and voltage level
3.3.8 Hysteretic Voltage Droop Algorithm for distributed control of the new DGDSA
3.4 RESULTS AND DISCUSSION
3.4.1 Selection of interconnection scheme,optimal voltage level and conductor size and levelized cost analysis
3.4.2 DC power flow analysis for a scaled-down hardware nanogrid implementation in a microgrid
3.4.3 The Proposed Architecture and Practical Deployment Challenges
3.5 CONCLUSIONS
CHAPTER4 HYBRID(PV-WIND)ENERGY STORAGE VIA CBBS FOR RURAL ELECTRIFICATION AND ITS IMPACT
4.1 INTRODUCTION
4.2 PROBLEM STATEMENT
4.3 PROPOSED STRUCTURE MODELLING
4.3.1 Energy Storage
4.3.2 Bi-level Structure
4.3.3 Bi-level Optimization Model
4.3.4 MPEC Formulation
4.4 RESULTS& DISCUSSION
4.4.1 Test data and implementation
4.4.2 Impact of Energy Storage
4.5 CONCLUSIONS
CHAPTER5 LINEAR FORMULATION OF UNIT COMMITMENT PROBLEM FOR RURAL ELECTRIFICATION
5.1 INTRODUCTION
5.2 PROBLEM STATEMENT
5.3 PROPOSED STRUCTURE MODELLING
5.2.1 UC Optimization Model for Community
5.2.2 Unit commitment between households or nearby villages(microgrids)
5.4 RESULTS& DISCUSSION
5.4.1 Test data and implementation
5.4.2 Impact on results
5.5 CONCLUSIONS
CHAPTER6 CONCLUSIONS AND FUTURE RECOMMENDATIONS
6.1 CONCLUSIONS
6.2 FUTURE RECOMMENDATIONS
REFERENCES
LIST OF PUBLICATIONS
本文编号:3385551
【文章来源】:江苏大学江苏省
【文章页数】:151 页
【学位级别】:博士
【文章目录】:
ACKNOWLEDGMENTS
abstract
CHAPTER1 INTRODUCTION
1.1 INTRODUCTION
1.2 PRESENT SCENARIO
1.3 SIGNIFICANCE OF THE STUDY
1.4 LITERATURE REVIEW
1.5 SUMMARY
CHAPTER2 DEVELOPMENT OF A HYBRID(PV-WIND)NANOGRID
2.1 INTRODUCTION
2.2 PROBLEM STATEMENT
2.3 THE PROPOSED ARCHITECTURE OF HYBRID(PV-WIND)NANOGRID
2.3.1 Solar Energy
2.3.2 Wind Energy
2.4 SIMULATION AND RESULTS
2.4.1 Tilted angle for sun radiation
2.4.2 PV Panel
2.4.3 Wind Turbine
2.5 SUMMARY
CHAPTER3 HYBRID(PV-WIND)BASED SCALABLE DC MICROGRID
3.1 INTRODUCTION
3.2 PROBLEM STATEMENT
3.3 THE PROPOSED DC MICROGRID ARCHITECTURE
3.3.1 Hybrid(PV-wind)nanogrid model
3.3.2 Solar Panel
3.3.3 Wind Turbine
3.3.4 DC-DC and AC-DC converters
3.3.5 Bidirectional Flyback Converter
3.3.6 Model village and interconnection of Microgrid Scheme
3.3.7 Power flow analysis for optimal selection of conductor size and voltage level
3.3.8 Hysteretic Voltage Droop Algorithm for distributed control of the new DGDSA
3.4 RESULTS AND DISCUSSION
3.4.1 Selection of interconnection scheme,optimal voltage level and conductor size and levelized cost analysis
3.4.2 DC power flow analysis for a scaled-down hardware nanogrid implementation in a microgrid
3.4.3 The Proposed Architecture and Practical Deployment Challenges
3.5 CONCLUSIONS
CHAPTER4 HYBRID(PV-WIND)ENERGY STORAGE VIA CBBS FOR RURAL ELECTRIFICATION AND ITS IMPACT
4.1 INTRODUCTION
4.2 PROBLEM STATEMENT
4.3 PROPOSED STRUCTURE MODELLING
4.3.1 Energy Storage
4.3.2 Bi-level Structure
4.3.3 Bi-level Optimization Model
4.3.4 MPEC Formulation
4.4 RESULTS& DISCUSSION
4.4.1 Test data and implementation
4.4.2 Impact of Energy Storage
4.5 CONCLUSIONS
CHAPTER5 LINEAR FORMULATION OF UNIT COMMITMENT PROBLEM FOR RURAL ELECTRIFICATION
5.1 INTRODUCTION
5.2 PROBLEM STATEMENT
5.3 PROPOSED STRUCTURE MODELLING
5.2.1 UC Optimization Model for Community
5.2.2 Unit commitment between households or nearby villages(microgrids)
5.4 RESULTS& DISCUSSION
5.4.1 Test data and implementation
5.4.2 Impact on results
5.5 CONCLUSIONS
CHAPTER6 CONCLUSIONS AND FUTURE RECOMMENDATIONS
6.1 CONCLUSIONS
6.2 FUTURE RECOMMENDATIONS
REFERENCES
LIST OF PUBLICATIONS
本文编号:3385551
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