FUELEAP Model-Based System Safety Analysis

Woodham, Kurt; Graydon, Patrick J.; Borer, Nicholas K.; Papathakis, Kurt P.; Stoia, Tina; Balan, Chellappa

doi:10.2514/6.2018-3362

Cited by 5 publications

(7 citation statements)

References 4 publications

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“…Hasan et al [23] and Hemm et al [24] utilized modeling and simulation tools to gain additional knowledge regarding hazard severity and probabilities while focusing on the operational safety paradigm. Papathakis et al [25] and Woodham et al [26] conducted safety assessments of novel electric propulsion technologies. However in all these, variants of traditional methods like FTA and FHA have been utilized with subject matter expert knowledge to conduct safety assessments of novel aircraft technologies.…”

Section: Background and Literaturementioning

confidence: 99%

“…In addition to the novel technologies being tested with the X-57 program, of interest in the present work are the tools and methods used to conduct safety analysis of such transformational aviation concepts. Research in this direction available in literature points towards the utilization of traditional methods to assess safety [25,26,45]. Having multiple propulsors, the effect of one or more propulsors failing must be considered to assess the safety of the aircraft.…”

Section: Case Study: the X-57 Aircraftmentioning

confidence: 99%

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Evaluation of Off-Nominal Performance and Reliability of a Distributed Electric Propulsion Aircraft during Early Design

Bendarkar

Sarojini

Harrison

et al. 2021

AIAA Scitech 2021 Forum

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General Aviation (GA) is likely to be at the forefront of a paradigm change in aviation, where the introduction of novel concepts such as Urban Air Mobility (UAM), architectures like −VTOL, and technologies like Distributed Electric Propulsion (DEP) are expected to make aircraft more efficient and reduce their environmental footprint. However, these architectures carry with them an uncertainty related to the off-nominal operational risk they pose. The limitations and off-nominal operational considerations generally postulated during traditional safety analysis may not be complete or correct for new technologies. While a lot of the literature surveyed focuses on improving traditional methods of safety analysis, it still does not completely address the limitations caused due to insufficient knowledge and experience with transformative technologies. The research objective of the present work is to integrate the Bayesian safety assessment framework developed previously by the authors with conceptual and 6-DoF performance models for DEP aircraft to evaluate off-nominal performance and reliability using information that is typically available in conceptual or preliminary design phases. A case study on the electric power architecture of the the NASA Maxwell X-57 Mod. IV is provided. A maximum potential flight path angle metric, as well as trimmability considerations using a 6-DoF model constructed using available literature help determine hazard severity of power degradation scenarios. Bayesian failure rate posteriors are constructed for the different components in the traction power system, which are used in a Bayesian decision framework. The results indicate that while most of the components in the traction power architecture of the X-57 Mod. IV are compliant with failure rate requirements generated, the batteries, cruise motors, and cruise motor-inverters do not meet those requirements.

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Section: Background and Literaturementioning

confidence: 99%

Section: Case Study: the X-57 Aircraftmentioning

confidence: 99%

Evaluation of Off-Nominal Performance and Reliability of a Distributed Electric Propulsion Aircraft during Early Design

Bendarkar

Sarojini

Harrison

et al. 2021

AIAA Scitech 2021 Forum

View full text Add to dashboard Cite

show abstract

“…This, combined with the battery, provides enough performance for the aircraft to maintain level flight or shallow drift-down performance, giving the operator more options for an expedited landing. These and other situations are discussed in the companion papers by Papathakis et al [5] and Woodham et al [7].…”

Section: B Hybrid-electric Sofc Power Systemmentioning

confidence: 95%

“…Finally, Section IV summarizes the results of this research. Other companion papers include: a more detailed description of the power system design [4], electrical integration of this power system into the X-57 [5], thermal cycle testing of SOFC hardware to assess suitability for aviation operations [6], system safety analysis of the FUELEAP X-57 demonstrator concept [7], and the use of model-based systems engineering frameworks to aid in the development of future demonstrator concepts [8].…”

mentioning

confidence: 99%

Design and Performance of a Hybrid-Electric Fuel Cell Flight Demonstration Concept

Borer

Geuther

Litherland

et al. 2018

2018 Aviation Technology, Integration, and Operations Conference

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this technology. These drawbacks have thus far limited market penetration in all but the smallest vehicle classes. Current approaches to airborne electricity generation revolve around storage of the energy in batteries onboard the aircraft, which greatly limits range and endurance, or generation of electricity by combustion of stored hydrocarbon fuel as part of a hybrid-electric architecture, which suffers from mass and efficiency challenges.Borer [1] outlined these approaches and recommended pursuit of an additional option to the portfolio of solutions available to store energy for airborne electric propulsion. Borer proposed the use of a hybrid-electric solution that generates electricity primarily from a Solid Oxide Fuel Cell (SOFC) fed from an onboard fuel reformer, which converts heavier hydrocarbons into products suitable to be consumed by the SOFC. To be viable, this power system needs to operate at a specific power level of at least 300 W/kg and an efficiency of 60%, referenced to the lower heating value (LHV) of the stored fuel. These characteristics represent significant advances in the state-of-the-art for hybrid-electric SOFC architectures -a recent National Academies report indicated that such architectures are capable of a specific power of 100 W/kg and an efficiency of 30-40% [2]. More recent research suggests that higher specific power and efficiency levels are achievable [3].This paper is one of a number of concurrent papers related to NASA's Fostering Ultra-Efficient, Low-Emitting Aviation Power (FUELEAP) project. The authors present a detailed application of a hybrid-electric, heavy-fuel, SOFC power system developed under FUELEAP. Specifically, this paper describes the integration of a 120 kW power system in place of the battery system used on NASA's X-57 "Maxwell" distributed electric propulsion (DEP) technology flight demonstrator. Section II provides background on FUELEAP and the X-57 program. Section III describes the integration of the hybrid-electric SOFC power architecture onto the X-57 and provides performance estimates for two different design spirals, as well as comparison to gasoline-fueled and battery-powered alternatives. Finally, Section IV summarizes the results of this research. Other companion papers include: a more detailed description of the power system design [4], electrical integration of this power system into the X-57 [5], thermal cycle testing of SOFC hardware to assess suitability for aviation operations [6], system safety analysis of the FUELEAP X-57 demonstrator concept [7], and the use of model-based systems engineering frameworks to aid in the development of future demonstrator concepts [8].

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“…NASA commissioned several investigations to contrast major design differences of UAM aircraft and explore the safety and reliability implications from the perspective of vehicle design, propulsion architecture and flight dynamics and control [32,[68][69][70][84][85]. The industry is pursuing the issues of UAM aircraft safety [93][94][95], particularly since EASA's issue of special conditions for VTOL certification and the proposed means of compliance [96][97]. EASA SC-VTOL-01 establishes certification criteria for vertical takeoff and landing vehicles with unique propulsion and control architectures, including distributing the flight controls and electric propulsion elements.…”

Section: Reliability and Safety Assessmentsmentioning

confidence: 99%

NASA concept vehicles and the engineering of advanced air mobility aircraft

Johnson

Silva

2021

Aeronaut. j.

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NASA is conducting investigations in Advanced Air Mobility (AAM) aircraft and operations. AAM missions are characterised by ranges below 300 nm, including rural and urban operations, passenger carrying as well as cargo delivery. Urban Air Mobility (UAM) is a subset of AAM and is the segment that is projected to have the most economic benefit and be the most difficult to develop. The NASA Revolutionary Vertical Lift Technology project is developing UAM VTOL aircraft designs that can be used to focus and guide research activities in support of aircraft development for emerging aviation markets. These NASA concept vehicles encompass relevant UAM features and technologies, including propulsion architectures, highly efficient yet quiet rotors, and aircraft aerodynamic performance and interactions. The configurations adopted are generic, intentionally different in appearance and design detail from prominent industry arrangements. Already these UAM concept aircraft have been used in numerous engineering investigations, including work on meeting safety requirements, achieving good handling qualities, and reducing noise below helicopter certification levels. Focusing on the concept vehicles, observations are made regarding the engineering of Advanced Air Mobility aircraft.

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FUELEAP Model-Based System Safety Analysis

Cited by 5 publications

References 4 publications

Evaluation of Off-Nominal Performance and Reliability of a Distributed Electric Propulsion Aircraft during Early Design

Evaluation of Off-Nominal Performance and Reliability of a Distributed Electric Propulsion Aircraft during Early Design

Design and Performance of a Hybrid-Electric Fuel Cell Flight Demonstration Concept

NASA concept vehicles and the engineering of advanced air mobility aircraft

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