Exploring advanced technology gas turbine engine design and performance for the Large Civil Tiltrotor (LCTR)

Snyder, Christopher A.

doi:10.2514/6.2014-3442

Cited by 9 publications

(12 citation statements)

References 3 publications

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“…Independent system studies performed by NASA and Boeing showed that advanced turboshaft engines with VSPT would have the benefits of a 13% lower Take-off Gross Weight (TOGW) and a 25-28% lower fuel burn for the NASA RVLT LCTR mission [67][68][69][70][71][72]. At takeoff, the LCTR main rotors and the VSPTs operate at 100% speed, while at cruise the rotors tilt forward and the VSPTs are slowed to 54% speed to enable higher efficiency.…”

Section: Variable Speed Power Turbine (Vspt) -Enabling Future Vertical Lift Propulsion Requirementsmentioning

confidence: 99%

NASA's Role in Gas Turbine Technology Development: Accelerating Technical Progress Via Collaboration Between Academia, Industry, and Government Agencies

Suder

2020

Journal of Turbomachinery

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Given the maturity of the gas turbine engine since its invention and considering the limited resources expected to be allocated for NASA aeronautics research and development, we ask the question are NASA technology investments still needed to enable future turbine engine-based propulsion systems? If so, what is NASA's unique role to justify NASA's investment? To address this topic, we first summarize NASA's role and contributions to turbine engine development, specific to both 1) NASA's role in conducting experiments to understand flow physics and provide relevant benchmark validation experiments for Computational Fluid Dynamics (CFD) code development, validation, and assessment; and 2) the impact of technologies resulting from NASA collaborations with industry, academia, and other government agencies. Note that the scope of the discussion is limited to the NASA technology contributions with which the author was intimately associated, and does not represent the entirety of the NASA contributions to turbine engine technology. The specific research, development, and demonstrations discussed herein were selected to both 1) provide a comprehensive review and reference list of the technology and its impact, and 2) identify NASA's unique role and highlight how NASA's involvement resulted in additional benefit to the gas turbine engine community. Secondly, we will discuss current NASA collaborations that are in progress and provide a status of the results. Finally, we discuss the challenges anticipated for future turbine engine-based propulsion systems for civil aviation and identify potential opportunities for collaboration where NASA involvement would be beneficial.

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Section: Variable Speed Power Turbine (Vspt) -Enabling Future Vertical Lift Propulsion Requirementsmentioning

confidence: 99%

NASA's Role in Gas Turbine Technology Development: Accelerating Technical Progress Via Collaboration Between Academia, Industry, and Government Agencies

Suder

2020

Journal of Turbomachinery

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“…The turboshaft motor drives the generator at a constant speed. Turboshaft engine power requirements as a function of vehicle speed are shown in Figure 3, where power levels are described in Table 1 based on engine ratings defined in Ref (10). Motor and generator power required refers to electric motor and turboshaft engine requirements for the mission respectively, and do not account for auxiliary power needs and losses.…”

Section: T II System Definition and Requirementsmentioning

confidence: 99%

Multi-point Design and Optimization of a Turboshaft Engine for Tiltwing Turboelectric VTOL Air Taxi

Chapman

2019

AIAA Scitech 2019 Forum

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“…Work continues on gas turbines to further improve efficiency and apply these gains to rotorcraft design (Snyder, 2014;Hendricks, Jones, and Gray, 2014). There are still significant gains to be achieved through turbomachinery component efficiency.…”

Section: Ongoing Propulsion Research Within Nasamentioning

confidence: 99%

Greener Helicopters

Russell

Young

Yamauchi

et al. 2015

Encyclopedia of Aerospace Engineering

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Helicopter and vertical takeoff and landing (VTOL) operations present multiple environmental challenges in a world where industrialized nations are adopting stricter regulations on air pollution and noise. New vehicles will need to be designed for minimal environmental impact, particularly with respect to CO 2 emissions and noise footprint. This chapter describes the issues confronting today's rotorcraft, and outlines technology options for developing VTOL vehicle designs with green propulsion systems, reducing rotorcraft noise, and applying “green metrics” to rotorcraft design.

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Exploring advanced technology gas turbine engine design and performance for the Large Civil Tiltrotor (LCTR)

Cited by 9 publications

References 3 publications

NASA's Role in Gas Turbine Technology Development: Accelerating Technical Progress Via Collaboration Between Academia, Industry, and Government Agencies

NASA's Role in Gas Turbine Technology Development: Accelerating Technical Progress Via Collaboration Between Academia, Industry, and Government Agencies

Multi-point Design and Optimization of a Turboshaft Engine for Tiltwing Turboelectric VTOL Air Taxi

Greener Helicopters

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