06-08-2012, 07:38 AM
working of a microcontroller based multi function solar tracking system and block diagram
06-08-2012, 07:38 AM
working of a microcontroller based multi function solar tracking system and block diagram
07-08-2012, 11:44 AM
to get information about the topic"microcontroller based solar tracking system" full report ppt and related topic refer the link bellow
https://seminarproject.net/Thread-microc...ing-system https://seminarproject.net/Thread-improv...ed-control http://seminarprojectsshowthread.php?mode=linear&tid=40031 https://seminarproject.net/Thread-avr-mi...r-tracking
04-10-2012, 04:45 PM
MICROCONTROLLER BASED SOLAR TRACKING SYSTEM
Solar Tracker Porposal.docx (Size: 98.06 KB / Downloads: 103) Introduction Renewable energy is rapidly gaining importance as an energy resource as fossil fuel prices fluctuate. At the educational level, it is therefore critical for engineering and technology students to have an understanding and appreciation of the technologies associated with renewable energy. One of the most popular renewable energy sources is solar energy. Many researches were conducted to develop some methods to increase the efficiency of Photo Voltaic systems (solar panels). One such method is to employ a solar panel tracking system .This project deals with a micro- controller based solar panel tracking system. Solar tracking enables more energy to be generated because the solar panel is always able to maintain a perpendicular profile to the sun’s rays. Development of solar panel tracking systems has been ongoing for several years now. As the sun moves across the sky during the day, it is advantageous to have the solar panels track the location of the sun, such that the panels are always perpendicular to the solar energy radiated by the sun. This will tend to maximize the amount of power absorbed by PV systems. It has been estimated that the use of a tracking system, over a fixed system, can increase the power output by 30% - 60%. The increase is significant enough to make tracking a viable preposition despite of the enhancement in system cost. It is possible to align the tracking heliostat normal to sun using electronic control by a micro controller. Design requirements are: 1) During the time that the sun is up, the system must follow the sun’s position in the sky. 2) This must be done with an active control, timed movements are wasteful. It should be totally automatic and simple to operate. The operator interference should be minimal and restricted to only when it is actually required. Objective The objective of this project is to control the position of a solar panel in accordance with the motion of sun. Brief Methodology: This project is designed with solar panels, LDR, ADC, Microcontroller, Stepper Motor and its driving circuit. In this project two LDRs are fixed on the solar panel at two distinct points. LDR (Light Dependant Resistor) varies the resistance depending upon the light fall. The varied resistance is converted into an analog voltage signal. The analog voltage signal is then fed to an ADC. ADC is nothing but analog to digital Converter which receives the two LDR voltage signals and converts them to corresponding digital signal. Then the converted digital signal is given as the input of the microcontroller. Microcontroller receives the two digital signals from the ADC and compares them. The LDR signals are not equal except for normal incidence of sunlight. When there is a difference between LDR voltage levels the microcontroller program drives the stepper motor towards normal incidence of sunlight. Solar Molding A solar model is the solution to a set of equations describing the physical processes occurring within the Sun. These equations are often divided into two subsets, the structure equations and the chemical evolution equations. In the very simplest cases, these equations are coupled nonlinear first-order ordinary differential equations, but more realistic models usually involve coupled nonlinear first-order partial differential equations. In either case, the equations cannot be solved analytically and thus must be solved numerically. Therefore, a solar model is usually comprised of a set of tables describing the conditions (chemical composition, density, luminosity, mass, pressure, temperature, etc.) at different depths in the star. Equations of Stellar Structure The physical variables involved in these equations are luminosity, mass, pressure, radius, and temperature. Other quantities such as density, energy generation rate, and opacity, are derived from these five variables. The equations of stellar structure are usually written with mass as the independent variable, not radius. One reason for this is that most stellar models assume that the star has constant mass over a given time but not constant radius. Indeed, we expect the radius of a star to vary over its lifetime. Equations of Chemical Evolution The equations of chemical evolution depend solely upon which nuclear processes are running in the interior of the star. In the Sun, the most important fusion process is the proton-proton chain (pp chain) which fuses four hydrogen atoms to one helium atom. However, another reaction network called the carbon-nitrogen-oxygen cycle (CNO cycle) is also active in the Sun, although it is much less important than the pp chain. In my model I keep track of five elements: hydrogen, two species of helium, carbon, and nitrogen. After making certain simplifying assumptions |
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