04691nam 2200529 450 991043830850332120221206101426.00-7680-8726-00-7680-8297-81-5231-0631-X10.4271/pt-177(CKB)3810000000287822(MiAaPQ)EBC5341835(CaBNVSL)mat08503523(IDAMS)0b000064887634e8(IEEE)8503523(EXLCZ)99381000000028782220181229d2016 uy engurcnu||||||||txtrdacontentcrdamediacrrdacarrierAircraft thermal management systems architectures /by Mark F. AhlersWarrendale, Pennsylvania (400 Commonwealth Dr., Wallendale PA USA) :Society of Automotive Engineers,2016.[Piscataqay, New Jersey] :IEEE Xplore,[2016]1 online resource (v, 99 pages) illustrationsPT ;177Society of Automotive Engineers. Electronic publications0-7680-8296-X Includes bibliographical references.1. Aircraft thermal management-heat sink challenge (2014-01-2193) / Dooley, M., Lui, N., Newman, R., and Lui, C -- 2. Integrated aircraft thermal management & power generation: Reconfiguration of a closed loop air cycle system as a Brayton cycle gas generator to support auxiliary electric power generation (2014-01-2192) / Abolmoali, P., Parrilla, J., and Hamed, A -- 3. Aircraft integration challenges and opportunities for distributed intelligent control, power, thermal management, diagnostic and prognostic systems (2014-01-2161) / Behbahani, A., Von Moll, A., Zeller, R., and Ordo, J -- 4. Thermal management investigations for fuel cell systems on-board commercial aircraft (2013-01-2274) / Vredenborg, E., and Thielecke, F -- 5. Power and thermal management for future aircraft (2013-01-2273) / Ganev, E., and Koerner, M -- 6. A highly stable two-phase thermal management system for aircraft (2012-01-2186) / Chen, W., Fogg, D., Izenson, M., and Kurwitz, C -- 7. Thermal management and power generation for directed energy weapons (2010-01-1781) / Patel, V. P., Koerner, M., Loeffelholz, D -- 8. Comparative analysis of thermal management architectures to address evolving thermal requirements of aircraft systems (2008-01-2905) / Homitz, J., Scaringe, R., Cole, G., Fleming, A., et al -- 9. Aircraft thermal management using loop heat pipes: Experimental simulation of high acceleration environments using the centrifuge table test bed (2006-01-3066) / Fleming, A., Leland, Q., Yerkes, K., Elston, L., et al -- 10. Evaluation of a vapor-compression thermal management system for reliability while operating under thermal transients (2010-01-1733) / Homitz, J., Scaringe, R., and Cole, G.Aircraft thermal management (ATM) is increasingly important to the design and operation of commercial and military aircraft due to rising heat loads from expanded electronic functionality, electric systems architectures, and the greater temperature sensitivity of composite materials compared to metallic structures. It also impacts engine fuel consumption associated with removing waste heat from an aircraft. More recently the advent of more electric architectures on aircraft, such as the Boeing 787, has led to increased interest in the development of more efficient ATM architectures by the commercial airplane manufacturers. The ten papers contained in this book describe aircraft thermal management system architectures designed to minimize airplane performance impacts which could be applied to commercial or military aircraft. Additional information on Aircraft Thermal Management System Architectures is available from SAE AIR 5744 issued by the AC-9 Aircraft Environmental System Committee and the SAE book Aircraft Thermal Management Integrated Analysis (PT-178). SAE AIR 5744 defines the discipline of aircraft thermal management system engineering while Aircraft Thermal Management Integrated Analysis discusses approaches to computer simulation of the simultaneous operation of all systems affecting thermal management on an aircraft.PT (Series) (Warrendale, Pa.) ;177.AerothermodynamicsAerodynamic heatingAerothermodynamics.Aerodynamic heating.629.134Ahlers Mark F.1244336CaBNVSLCaBNVSLCaBNVSLBOOK9910438308503321Aircraft thermal management2886629UNINA