CHAPTER ONE
INTRODUCTION
1.1 BACKGROUND TO THE STUDY
The use of renewable energy increased greatly just after the first big oil crisis in the late seventies. At that time, economic issues were the most important factors, hence interest in such processes decreased when oil prices fell. The current resurgence of interest in the use of renewable energy is driven by the need to reduce the high environmental impact of fossil-based energy systems. Harvesting energy on a large scale is undoubtedly one of the main challenges of our time. Future energy sustainability depends heavily on how the capacity of renewable energyis improved in the next few decades.
Although in most power-generating systems, the main source of energy (the fuel) can be manipulated, this is not true for solar and wind energies (Valenzuela, et al, 2004). The main problems with these energy sources are cost and availability, wind and solar power are not always available where and when needed. Unlike conventional sources of electric power, these renewable sources are not “dispatchable”—the power output cannot be controlled. Daily and seasonal effects and limited predictability result in intermittent generation. Some manufacturers has released products to facilitate the integration of renewable energy but the researcher is examining ways of improving the capacity of renewable power system using solar power panel (Camacho et al, 2007).
Industry must overcome a number of technical issues to deliver renewable energy in significant quantities. Control is one of the key enabling technologies for the deployment of renewable energy systems. Solar power requires effective use of advanced control techniques. In addition, reliable electric supply cannot be achieved without extensive use of control technologies at all levels.
Solar power plant exhibit changing dynamics, nonlinearities, and uncertainties—challenges that require advanced control strategies to solve effectively. The use of more efficient control strategies would not only increase the performance of these systems, but would increase the number of operational hours of solar and wind plants and thus reduce the cost per kilowatt-hour (KWh) produced.
The solar have tremendous potential for fulfilling the world’s energy needs (White House, 2010).
One of the greatest scientific and technological opportunities researchers are faced with is approaches to developing efficient ways to collect, convert, store, and utilize solar energy at an affordable cost. The solar power reaching the earth’s surface is about 86,000 TW. Covering 0.22% of our planet with solar collectors with an efficiency of 8% would be enough to satisfy the current global power consumption. Estimates are that an energy project utilizing concentrating solar power (CSP) technology deployed over an area of approximately 160 x 160 km in the Southwest U.S. could produce enough power for the entire U.S. consumption.
Solar-sourced electricity can be generated either directly using photovoltaic (PV) cells or indirectly by collecting and concentrating the solar power to produce steam, which is then used to drive a turbine to provide the electric power (CSP).
Concentrating solar thermal systems use optical devices (usually mirrors) and sun-tracking systems to concentrate a large area of sunlight onto a smaller receiving area. The concentrated solar energy is then used as a heat source for a conventional power plant. A wide range of concentrating technologies exists, the main ones being parabolic troughs, solar dishes, linear Fresnel reflectors, and solar power towers. The primary purpose of concentrating solar energy is to produce high temperatures and therefore high thermodynamic efficiencies.
Parabolic trough systems are the most commonly used CSP technology. A parabolic trough consists of a linear parabolic mirror that reflects and concentrates the received solar energy onto a tube (receiver) positioned along the focal line. The heat transfer fluid is pumped through the receiver tube and picks up the heat transferred through the receiver tube walls. The parabolic mirror follows the sun by tracking along a single axis. Linear Fresnel reflectors use various thin mirror strips to concentrate sunlight onto tubes containing heat transfer fluid. Higher concentration can be obtained, and the mirrors are cheaper than parabolic mirrors, but a more complex tracking mechanism is needed.
1.2 STATEMENT OF THE PROBLEM
The uncertainty and intermittency of solar generation are major complications that must be addressed before the full potential of this renewable power system can be reached. The researcher provides an overview of a solar power panel withan evolution of electricity networks toward greater reliance on communications, computation, and control which is a way aimed at improving it.
The application of advanced digital technologies (i.e., microprocessor-based measurement and control, communications, computing, and information systems) which are expected to greatly improve the reliability, security, interoperability, and efficiency of the electrical grid, while reducing environmental impacts and promoting economic growth will be considered.
1.3 OBJECTIVES OF THE STUDY
The following are the objectives of this study:
1.4 RESEARCH QUESTIONS
1.6 SIGNIFICANCE OF THE STUDY
The following are the significance of this study:
1.7 SCOPE/LIMITATIONS OF THE STUDY
This study will cover approaches at improving the existing solar power technology with a view of optimizing the operation of the system and minimizing environmental impacts.
LIMITATION OF STUDY
REFERENCES
E.F. Camacho, F. Rubio, M. Berenguel, and L. Valenzuela. “A survey on control schemes for distributed solar collector fields (part 1 and 2),” Solar Energy, vol. 81, pp. 1240-1272, 2007
L. Valenzuela, E. Zarza, M. Berenguel, and E.F. Camacho. “Direct steam generation in solar boilers,” IEEE Control Systems Magazine, vol. 24, no. 2, pp. 15-29, 2004.
White House. Weekly address [Online], July 3, 2010. Available at, http://www.whitehouse.gov/blog/ 2010/07/03/weekly-address-a-solar-recovery#.
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