Full-Scale Turbofan Demonstration of a Deployable Engine Air-Brake for Drag Management Applications

Shah, Parikshit; Pfeiffer, Gordon; Davis, Rory; Hartley, Thomas; Spakovszky, Z. S.

doi:10.1115/gt2016-56708

Cited by 2 publications

(1 citation statement)

References 12 publications

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“…The decent angle of an aircraft is limited by the amount of drag that can be created. Recent research has examined using an engine airbrake to increase drag during descent [222]. Drag could be increased for AEA by allowing some of the propulsors to windmill, which may recover some energy as well.…”

Section: Batteriesmentioning

confidence: 99%

Technical and environmental assessment of all-electric 180-passenger commercial aircraft

Gnadt

Speth

Sabnis

et al. 2019

Progress in Aerospace Sciences

181

103

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Aviation emissions contribute to climate change, and all-electric aircraft offer an opportunity for zero in-flight emissions. Over the past decade, more than 50 all-electric conceptual, experimental, and commercial aircraft have been researched, with a particular focus on light aircraft. These designs are reviewed, along with progress in battery technology. An all-electric aircraft design and optimization program, TASOPTe, has been developed from an existing version for conventionally-powered aircraft, TASOPT. Both programs are largely based on first-principles, enabling the design of aircraft with unusually short design ranges. A series of optimized 180-passenger aircraft based on the Airbus A320neo configuration are designed and evaluated at 200-1600 nmi design ranges with 2-10 propulsors and 400-2000 Wh/kg batteries. The performance of these all-electric aircraft is compared to advanced conventionally-powered aircraft optimized for the same design ranges. Optimized all-electric aircraft are found to use two or four propulsors, depending on the design range and specific energy assumed. The design range limits for each specific energy are determined, which are restricted by aircraft weight and performance penalties. A factor of four increase in battery pack specific energy from current values of 200 Wh/kg to 800 Wh/kg enables 500 nmi flights. However, a lower design range of 300 nmi provides improved energy and environmental performance. The required grid power generation circumstances for commercial all-electric aircraft to become net environmentally beneficial is determined for each specific energy assumption. The entire energy conversion chain, including charging, transport, and discharging of electrical energy, is considered. Despite the higher total energy use, narrow-body all-electric aircraft have the potential for lower equivalent CO 2 emissions if the electrical grid transitions toward renewable energy. This is largely enabled by the complete elimination of all highaltitude emissions, which would remove associated non-CO 2 warming. I would like to thank my advisor, Professor Steven Barrett, for accepting me into his lab midyear, allowing me to work on an interesting research project, and providing valuable guidance and support. Thank you Jayant Sabnis, Ray Speth, and Professor Mark Drela as well for many helpful discussions. To my lab mates and friends in LAE, especially Akshat, Tim, and Guillaume, thank you for your advice and friendship. Thank you to my close friends both at MIT and across the country for your encouragement and confidence in me. I would like to give a shout out to the AeroAstro Ballers, Bows, G 3, the 125ers, and the Esteemed Squad. A special thank you to Patrik for being my closest friend for over a decade. For your continuous supply of energy and inspiration, thank you Mr. Hyde and Mr. Shakur, respectively. Finally, and most importantly, I am deeply grateful for the love and encouragement from my family. Thank you to my many cousins, aunts, and uncles,. especially Aunt Char and Uncl...

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Section: Batteriesmentioning

confidence: 99%