Exergy Analysis and Design Optimization for Aerospace Vehicles and Systems

丛 书 名：Progress in Astronautics and Aeronautics

作     者：David J. Moorhouse Jose A. Camberos 

I S B N：(纸本) 9781600868399 

出 版 社：American Institute of Aeronautics and Astronautics  Inc. 

出 版 年：2011年

页      数：658页

主 题 词：Aerodynamics Aeronautical Engineering Aeronautics Aerospace Engineering Aerospace Sciences Air Forces Air Traffic Control Air Traffic Management Airbreathing Jet Engine Aircraft Components and Structure Aircraft Conceptual Design Aircraft Control Aircraft Design Aircraft Engines Aircraft Flight Control System Aircraft Operations Aircraft Operations and Technology Aircraft Performance Aircraft Stability and Control Aircraft Systems Aircraft Wing Components Aircraft Wing Design Aircrafts Airfoil Astronautics Aviation Combat Aircraft Combustion Chambers Combustors Compressors Computational Fluid Dynamics Coolant Cooling Technology Energy Energy Conservation Energy Consumption Energy Conversion Energy Economics Energy Forms Energy Forms, Production and Conversion Energy Production Enthalpy Entropy Finite Element Method Flight Control Surfaces Fluid Dynamics Fossil Fuels Fuel Injection Fuels Gas Laws Gas Turbine Heat Conduction Heat Engines Heat Exchangers Heat Transfer Heating, Ventilating, and Air Conditioning Ideal Gas Ignition Systems Jet Engines Laws of Thermodynamics Mass Transfer Military Aircraft Military Aviation Non-Renewable Energy Petroleum Power Station Propellant Propulsion and Power Ramjet Rocket Engine Rocketry Scramjet Thermal Control and Protection Thermodynamic Free Energy Thermodynamic Process Thermodynamic Properties Thermodynamics Thermophysics and Heat Transfer Turbines Turbomachinery Wind Power Wing Configurations Wing Planforms 

学科分类：08[工学] 082501[工学-飞行器设计] 0825[工学-航空宇航科学与技术] 

摘      要：Recognizing a critical need for a holistic approach to systems integration and multidisciplinary analysis and design optimization, volume editors Camberos and Moorhouse and the contributing authors pioneered the application of a powerful scientific principle, the second law of thermodynamics, for aerospace engineering. Exergy Analysis and Design Optimization for Aerospace Vehicles and Systems illustrates how they applied this law to advance aerospace systems analysis and design optimization. They set forth a comprehensive research program incorporating a systematic theoretical basis for constructing the proper formulas quantifying exergy balance, development of new computational capabilities for calculating exergy destruction, and exploration of novel approaches for system-level design. To enable rational progress in this unorthodox aerosciences domain, they developed a conceptual framework for constructing performance metrics across multiple disciplines to map work-potential losses as a common currency. Concepts discussed include identification of the upper limits on engineering system performance using the second law of thermodynamics Design methodology integration with tools developed in CFD and MDA/MDO Application of exergy methods to all levels of flight vehicle design Future directions, including constructal theory, quantum thermodynamics, and numerical methods Recognizing a critical need for a holistic approach to systems integration and multidisciplinary analysis and design optimization, volume editors Camberos and Moorhouse and the contributing authors pioneered the application of a powerful scientific principle, the second law of thermodynamics, for aerospace engineering. Exergy Analysis and Design Optimization for Aerospace Vehicles and Systems illustrates how they applied this law to advance aerospace systems analysis and design optimization. They set forth a comprehensive research program incorporating: A systematic theoretical basis for constructin