Medium and high temperature solar processes

Medium and High Temperature Solar Processes discusses the principles and economic viability of medium- and high-temperature solar processes. This book is organized into seven chapters that focus on the second law of thermodynamics and its use in matching solar collection methods to thermal processes. It also provides general design guidelines for small- and intermediate-scale applications of solar processes. The opening chapter presents an overview of energy use patterns in the United States and of the various solar-thermal processes considered in the book. The concepts of economics of solar systems and possible environmental impacts are also summarized. Chapter 2 deals with the quantity, geographic availability, and quality of solar radiation, with a particular emphasis on beam or direct radiation since it has the highest thermodynamic availability and is used by most elevated-temperature collectors. This chapter also describes the trigonometry of various solar tracking modes and optical properties of materials. Chapter 3 considers selected topics on thermodynamics and heat transfer, including various heat engine designs and their first and second law efficiencies; radiation heat transfer; and the properties of selective surfaces usable at high temperature. Chapter 4 covers the components and systems for medium-temperature processes, such as concentrating collectors, thermal storage, heat exchangers, and energy transport systems. Chapter 5 treats systems for power production, shaft power, industrial process heat, and total energy. Chapter 6 presents engineering design data for high-temperature collectors and their use in solar furnaces; central solar power plants; distributed power plants; and solar thermionics. The concluding chapter addresses the economics of the foregoing systems with an emphasis on methods and principles of analysis.

Preface1 Prologue I. Introduction II. Solar System Economics III. Environmental Impacts of Solar Systems2 Principles of Solar Radiation and Optics I. Introduction II. Terrestrial and Extraterrestrial Beam Radiation III. Solar Radiation Geometry IV. Beam Radiation Intercepted by Surfaces V. The Solar Energy Resource VI. Instantaneous and Hourly Solar Radiation Calculations VII. Daily Solar Radiation Calculations VIII. Monthly Radiation Calculations IX. Selected Topics in Optics3 Selected Topics in Thermodynamics and Heat Transfer for Elevated-Temperature Solar Processes I. Thermodynamic Principles II. Conduction Heat Transfer III. Convection Heat Transfer IV. Radiation Heat Transfer V. Combined Heat Transfer Modes-Example Calculation4 Medium-Temperature Solar Collectors and Ancillary Components I. Concentration of Sunlight II. Collectors for Medium-Temperature Solar Processes III. Ancillary Components of Solar-Thermal Systems5 Medium-Temperature Solar Processes I. Distributed Solar Power Production Systems II. Industrial Process Heat III. Shaft Work Production IV. Solar Total Energy Systems (STESs) V. Long-Term Performance of Medium-Temperature Solar Processes6 High-Temperature Solar Processes I. Compound-Curvature Solar Concentrators II. Solar Furnaces III. Central Receiver Solar-Thermal Power Systems IV. High-Temperature Distributed Solar Power Production V. Solar Thermionics VI. Long-Term Performance of High-Temperature Solar Processes7 Economic Analysis of Solar-Thermal Systems I. Economic Analysis of Solar-Thermal Systems II. Selected Topics in Engineering Economics III. The Solar System Cost Equation IV. Production Functions V. Optimal System Selection Appendix A Tables Appendix Nomenclature References Index