Anna University Syllabus - Anna University ME Syllabus
EY7005 SOLAR ENERGY TECHNOLOGIES Syllabus | Anna University ME Energy Engineering Second Semester Syllabus Regulation 2013. Below is the Anna University 2013 Regulation Syllabus for 2nd Semester for ME Energy engineering, Textbooks, Reference books, Exam portions, Question Bank, Previous year question papers, Model question papers, Class notes, Important 2 marks, 8 marks, 16 marks topics.
It is applicable for all students admitted in the Academic year 2013-2014 onwards for all its Affiliated institutions in Tamil Nadu.
Anna University Chennai Syllabus
EY7005 SOLAR ENERGY TECHNOLOGIES L T P C 3 0 0 3
AIM:
To understand the fundamentals of solar energy and its conversion techniques for both thermal and
electrical energy applications
21
OBJECTIVES:
To learn and study the radiation principles with respective solar energy estimation
To learn about PV technology principles and techniques of various solar cells / materials for lister
energy conversion
To learn economical and environmental merits of solar energy for variety applications
UNIT I SOLAR RADIATION AND COLLECTORS 9
Solar angles – Sun path diagrams – Radiation - extraterrestrial characteristics - measurement and
estimation on horizontal and tilted surfaces - flat plate collector thermal analysis - testing methodsevacuated
tubular collectors - concentrator collectors – classification - design and performance
parameters - tracking systems - compound parabolic concentrators - parabolic trough concentrators -
concentrators with point focus - Heliostats – performance of the collectors
UNIT II SOLAR THERMAL TECHNOLOGIES 9
Principle of working, types, design and operation of - Solar heating and cooling systems - Thermal
Energy storage systems – Solar Desalination – Solar cooker : domestic, community – Solar pond –
Solar drying
UNIT III SOLAR PV FUNDAMENTALS 9
Semiconductor – properties - energy levels - basic equations of semiconductor devices physics. Solar
cells - p-n junction: homo and hetro junctions - metal-semiconductor interface - dark and illumination
characteristics - figure of merits of solar cell - efficiency limits - variation of efficiency with band-gap
and temperature - efficiency measurements - high efficiency cells – Solar thermo-photovoltaics.
UNIT IV SPV SYSTEM DESIGN AND APPLICATIONS 9
Solar cell array system analysis and performance prediction- Shadow analysis: reliability - solar cell
array design concepts - PV system design - design process and optimization - detailed array design -
storage autonomy - voltage regulation - maximum tracking - centralized and decentralized SPV
systems - stand alone - hybrid and grid connected system - System installation - operation and
maintenances - field experience - PV market analysis and economics of SPV systems
UNIT V SOLAR PASSIVE ARCHITECTURE 9
Thermal comfort - bioclimatic classification – passive heating concepts: direct heat gain - indirect heat
gain - isolated gain and sunspaces - passive cooling concepts: evaporative cooling - Radiative cooling
- application of wind, water and earth for cooling; shading - paints and cavity walls for cooling - roof
radiation traps - earth air-tunnel. – energy efficient landscape design - thermal comfort
TOTAL: 45 PERIODS
OUTCOME:
1. Able to suggest and design a solar thermal based applications for a community
2. Will become expert in the design of solar photovoltaic based power systems for both domestic and
industrial applications
3. Have the potential to apply the concept of utilization of solar energy for the said application in a
economical way.
REFERENCES
1. Goswami, D.Y., Kreider, J. F. and & Francis., Principles of Solar Engineering, Taylor and Francis,
2000
2. Chetan Singh Solanki, Solar Photovoltatics – Fundamentals, Technologies and Applications, PHI
Learning Private limited, 2011
3. Sukhatme S P, J K Nayak, Solar Energy – Principle of Thermal Storage and collection, Tata
McGraw Hill, 2008.
4. Solar Energy International, Photovoltaic – Design and Installation Manual – New Society
Publishers, 2006
5. Roger Messenger and Jerry Vnetre, Photovoltaic Systems Engineering, CRC Press, 2010.
EY7005 SOLAR ENERGY TECHNOLOGIES L T P C 3 0 0 3
AIM:To understand the fundamentals of solar energy and its conversion techniques for both thermal and
electrical energy applications
21
OBJECTIVES:
To learn and study the radiation principles with respective solar energy estimation
To learn about PV technology principles and techniques of various solar cells / materials for lister
energy conversion
To learn economical and environmental merits of solar energy for variety applications
UNIT I SOLAR RADIATION AND COLLECTORS 9
Solar angles – Sun path diagrams – Radiation - extraterrestrial characteristics - measurement and
estimation on horizontal and tilted surfaces - flat plate collector thermal analysis - testing methodsevacuated
tubular collectors - concentrator collectors – classification - design and performance
parameters - tracking systems - compound parabolic concentrators - parabolic trough concentrators -
concentrators with point focus - Heliostats – performance of the collectors
UNIT II SOLAR THERMAL TECHNOLOGIES 9
Principle of working, types, design and operation of - Solar heating and cooling systems - Thermal
Energy storage systems – Solar Desalination – Solar cooker : domestic, community – Solar pond –
Solar drying
UNIT III SOLAR PV FUNDAMENTALS 9
Semiconductor – properties - energy levels - basic equations of semiconductor devices physics. Solar
cells - p-n junction: homo and hetro junctions - metal-semiconductor interface - dark and illumination
characteristics - figure of merits of solar cell - efficiency limits - variation of efficiency with band-gap
and temperature - efficiency measurements - high efficiency cells – Solar thermo-photovoltaics.
UNIT IV SPV SYSTEM DESIGN AND APPLICATIONS 9
Solar cell array system analysis and performance prediction- Shadow analysis: reliability - solar cell
array design concepts - PV system design - design process and optimization - detailed array design -
storage autonomy - voltage regulation - maximum tracking - centralized and decentralized SPV
systems - stand alone - hybrid and grid connected system - System installation - operation and
maintenances - field experience - PV market analysis and economics of SPV systems
UNIT V SOLAR PASSIVE ARCHITECTURE 9
Thermal comfort - bioclimatic classification – passive heating concepts: direct heat gain - indirect heat
gain - isolated gain and sunspaces - passive cooling concepts: evaporative cooling - Radiative cooling
- application of wind, water and earth for cooling; shading - paints and cavity walls for cooling - roof
radiation traps - earth air-tunnel. – energy efficient landscape design - thermal comfort
TOTAL: 45 PERIODS
OUTCOME:
1. Able to suggest and design a solar thermal based applications for a community
2. Will become expert in the design of solar photovoltaic based power systems for both domestic and
industrial applications
3. Have the potential to apply the concept of utilization of solar energy for the said application in a
economical way.
REFERENCES
1. Goswami, D.Y., Kreider, J. F. and & Francis., Principles of Solar Engineering, Taylor and Francis,
2000
2. Chetan Singh Solanki, Solar Photovoltatics – Fundamentals, Technologies and Applications, PHI
Learning Private limited, 2011
3. Sukhatme S P, J K Nayak, Solar Energy – Principle of Thermal Storage and collection, Tata
McGraw Hill, 2008.
4. Solar Energy International, Photovoltaic – Design and Installation Manual – New Society
Publishers, 2006
5. Roger Messenger and Jerry Vnetre, Photovoltaic Systems Engineering, CRC Press, 2010.
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