InfoCoBuild

Design of Photovoltaic Systems

Design of Photovoltaic Systems. Instructor: Prof. L. Umanand, Department of Electrical Engineering, IISc Bangalore. This course is a design oriented course aimed at photovoltaic system design. The course begins by discussing the PV cell electrical characteristics and interconnections. Estimation of insolation and PV sizing is addressed in some detail. Maximum power point tracking and circuits related to it are discussed. Later, applications related to peltier refrigeration, water pumping, grid connection and micro grids are discussed in detail. Lastly, a brief discussion on life cycle costing is also discussed in order to bring in a measure of completeness to the course. (from nptel.ac.in)

Lecture 81 - Peltier Cooling


Go to the Course Home or watch other lectures:

The PV Cell
Lecture 01 - A Historical Perspective
Lecture 02 - PV Cell Characteristics and Equivalent Circuit
Lecture 03 - Model of PV Cell
Lecture 04 - Short Circuit, Open Circuit and Peak Power Parameters
Lecture 05 - Datasheet Study
Lecture 06 - Cell Efficiency
Lecture 07 - Effect of Temperature
Lecture 08 - Temperature Effect Calculation Example
Lecture 09 - Fill Factor
Lecture 10 - PV Cell Simulation
Series and Parallel Interconnection
Lecture 11 - Identical Cells in Series
Lecture 12 - Load Line
Lecture 13 - Non-identical Cells in Series
Lecture 14 - Protecting Cells in Series
Lecture 15 - Interconnecting Cells in Series
Lecture 16 - Simulation of Cells in Series
Lecture 17 - Identical Cells in Parallel
Lecture 18 - Non-Identical Cells in Parallel
Lecture 19 - Protecting Cells in Parallel
Lecture 20 - Interconnecting Modules
Lecture 21 - Simulation of Cells in Parallel
Lecture 22 - Practicals - Measuring I-V Characteristics
Lecture 23 - Practicals - PV Source Emulation
Energy from Sun
Lecture 24 - Introduction
Lecture 25 - Insolation and Irradiance
Lecture 26 - Insolation Variation with Time of Day
Lecture 27 - Earth Centric Viewpoint and Declination
Lecture 28 - Solar Geometry
Lecture 29 - Insolation on a Horizontal Flat Plate
Lecture 30 - Energy on a Horizontal Flat Plate
Lecture 31 - Sunrise and Sunset Hour Angles
Lecture 32 - Examples
Incident Energy Estimation
Lecture 33 - Energy on a Tilted Flat Plate
Lecture 34 - Energy Plots on Octave
Lecture 35 - Atmospheric Effects
Lecture 36 - Airmass
Lecture 37 - Energy with Atmospheric Effects
Lecture 38 - Clearness Index
Lecture 39 - Clearness Index and Energy Scripts in Octave
Sizing PV
Lecture 40 - Sizing PV for Applications without Batteries
Lecture 41 - Sizing PV Examples
Lecture 42 - Batteries - Intro
Lecture 43 - Batteries - Capacity
Lecture 44 - Batteries - C-rate
Lecture 45 - Batteries - Efficiency
Lecture 46 - Batteries - Energy and Power Densities
Lecture 47 - Batteries - Comparison
Lecture 48 - Battery Selection
Lecture 49 - Other Energy Storage Methods
Lecture 50 - PV System Design - Load Profile
Lecture 51 - PV System Design - Days of Autonomy and Recharge
Lecture 52 - PV System Design - Battery Size
Lecture 53 - PV System Design - PV Array Size
Lecture 54 - Design Toolbox in Octave
Maximum Power Point Tracking
Lecture 55 - MPPT Concept
Lecture 56 - Input Impedance of DC-DC Converters - Boost Converter
Lecture 57 - Input Impedance of DC-DC Converters - Buck Converter
Lecture 58 - Input Impedance of DC-DC Converters - Buck-Boost Converter
Lecture 59 - Input Impedance of DC-DC Converters - PV Module in SPICE
Lecture 60 - Input Impedance of DC-DC Converters - Simulation - PV and DC-DC Interface
MPPT Algorithms
Lecture 61 - Impedance Control Methods
Lecture 62 - Impedance Control Methods - Reference Cell - Voltage Scaling
Lecture 63 - Impedance Control Methods - Reference Cell - Current Scaling
Lecture 64 - Impedance Control Methods - Reference Cell - Sampling Method
Lecture 65 - Impedance Control Methods - Reference Cell - Power Slope Method
Lecture 66 - Impedance Control Methods - Reference Cell - Power Slope Method (cont.)
Lecture 67 - Impedance Control Methods - Reference Cell - Hill Climbing Method
Lecture 68 - Practical Points - Housekeeping Power Supply
Lecture 69 - Practical Points - Gate Driver
Lecture 70 - Practical Points - MPPT for Non-resistive Loads
Lecture 71 - Simulation of MPPT
PV-Battery Interfaces
Lecture 72 - Direct PV-Battery Connection
Lecture 73 - Charge Controller
Lecture 74 - Battery Charger - Understanding Current Control
Lecture 75 - Battery Charger - Slope Compensation
Lecture 76 - Battery Charger - Simulation of Current Control
Lecture 77 - Batteries in Series - Charge Equalisation
Lecture 78 - Batteries in Parallel
Peltier Cooling
Lecture 79 - Peltier Device - Principle
Lecture 80 - Peltier Element - Datasheet
Lecture 81 - Peltier Cooling
Lecture 82 - Thermal Aspects
Lecture 83 - Heat Transfer by Conduction
Lecture 84 - Heat Transfer by Convection
Lecture 85 - Thermal Aspects - A Peltier Refrigeration Example
Lecture 86 - Thermal Aspects - Radiation and Mass Transport
Lecture 87 - Demo of Peltier Cooling
PV and Water Pumping
Lecture 88 - Water Pumping Principle
Lecture 89 - Hydraulic Energy and Power
Lecture 90 - Total Dynamic Head
Lecture 91 - Numerical Solution - Colebrook Formula
Lecture 92 - Octave Script for Head Calculation
Lecture 93 - PV and Water Pumping Examples
Lecture 94 - Octave Script for Hydraulic Power
Lecture 95 - Centrifugal Pump
Lecture 96 - Reciprocating Pump
Lecture 97 - PV Power
Lecture 98 - Pumped Hydro Application
PV-Grid Interface I
Lecture 99 - Grid Connection Principle
Lecture 100 - PV to Grid Topologies, Part I
Lecture 101 - PV to Grid Topologies, Part II
Lecture 102 - PV to Grid Topologies, Part III
Lecture 103 - 3PH D-Q Controlled Grid Connection Intro
Lecture 104 - 3PH D-Q Controlled Grid Connection: DQ Axis Theory
Lecture 105 - 3PH D-Q Controlled Grid Connection: AC to DC Transformations
Lecture 106 - 3PH D-Q Controlled Grid Connection: DC to AC Transformations
Lecture 107 - 3PH D-Q Controlled Grid Connection: Complete 3PH Grid Connection
Lecture 108 - 1PH D-Q Controlled Grid Connection
Lecture 109 - 3PH PV Grid Interface Example
Interface II and Life Cycle Costing
Lecture 110 - SVPWM - Discrete Implementation
Lecture 111 - SVPWM - Analog Implementation
Lecture 112 - Application of Integrated Magnetics
Lecture 113 - Life Cycle Costing: Growth Models
Lecture 114 - Life Cycle Costing: Growth Model Examples
Lecture 115 - Life Cycle Costing: Annual Payment and Present Worth Factor
Lecture 116 - Life Cycle Costing: LCC with Example
Lecture 117 - Life Cycle Costing: LCC Example (cont.)
Lecture 118 - Life Cycle Costing: LCC Example (cont.)