Method for simulating the performance of a boundary layer ingesting propulsion system at design and off-design

Goldberg, Chana; Nalianda, Devaiah; MacManus, David G.; Pilidis, Pericles; Felder, James L.

doi:10.1016/j.ast.2018.04.026

Cited by 21 publications

(12 citation statements)

References 11 publications

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“…The fuel is to be stored at 21.5K and 1.25bar, so insulation will require a great deal of attention. The authors based the tank design philosophy on expanded analytical studies based on previous Cranfield work (16)(17)(18) . The tanks must be insulated to prevent heat leakage into the liquid hydrogen with no need for an active cooling system.…”

Section: Fuel Tank Integrationmentioning

confidence: 99%

Propulsion system integration for a first-generation hydrogen civil airliner?

2021

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An unusual philosophical approach is proposed here to decarbonise larger civil aircraft that fly long ranges and consume a large fraction of civil aviation fuel. These inject an important amount of carbon emissions into the atmosphere, and holistic decarbonising solutions must consider this sector. A philosophical–analytical investigation is reported here on the feasibility of an airliner family to fly over long ranges and assist in the elimination of carbon dioxide emissions from civil aviation. Backed by state-of-the-art correlations and engine performance integration analytical tools, a family of large airliners is proposed based on the development and integration of the body of a very large two-deck four-engine airliner with the engines, wings and flight control surfaces of a very long-range twin widebody jet. The proposal is for a derivative design and not a retrofit. This derivative design may enable a swifter entry to service. The main contribution of this study is a philosophical one: a carefully evaluated aircraft family that appears to have very good potential for first-generation hydrogen-fuelled airliners using gas turbine engines for propulsion. This family offers three variants: a 380-passenger aircraft with a range of 3,300nm, a 330-passenger aircraft with a range of 4,800nm and a 230-passenger aircraft with a range of 5,500nm. The latter range is crucially important because it permits travel from anywhere in the globe to anywhere else with only one stop. The jet engine of choice is a 450kN high-bypass turbofan.

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Section: Fuel Tank Integrationmentioning

confidence: 99%

Propulsion system integration for a first-generation hydrogen civil airliner?

2021

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“…This condition can lead to differences in variables. Some of the calculated data are shown in Tables [18][19][20].…”

Section: High-altitude Cruisementioning

confidence: 99%

“…These models were applied to simplify the calculation while ensuring a certain degree of accuracy. Goldberg et al [18] developed a method to match propulsion system flow and tube flow to simulate the internal flow field under boundary layer inhalation and validated it with NASA's N3-X model. They found that the inlet distortion affected thrust more remarkably than fan efficiency.…”

Section: Introductionmentioning

confidence: 99%

Power Fan Design of Blended-Wing-Body Aircraft with Distributed Propulsion System

Jia

2021

International Journal of Aerospace Engineering

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A blended-wing-body aircraft has the advantages of high lift-to-drag ratio, low noise, and high economy compared with traditional aircraft. It is currently a solution with great potential to become a future civilian passenger aircraft. However, most airplanes with this layout use distributed power, and the power system is on the back of the fuselage, with embedded or back-supported engines. This type of design causes the boundary layer suction effect. The boundary layer ingestion (BLI) effect can fill the wake of the aircraft and improve the propulsion efficiency of the engine. However, it causes huge design difficulties, especially when the aircraft and the engine are strongly coupled. In this paper, an aircraft with a coupled engine configuration is studied. The internal and external flow fields are calculated through numerical simulation. A realistic calculation model is obtained through the coupling of boundary conditions. On the basis of the influence of the external flow on the internal flow under the coupled condition, the influence of the BLI effect on the aerodynamic performance of the fan is investigated.

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“…Boundary layer ingestion has stood out as a solution to improve both aerodynamics and propulsion performance [1][2][3]. The aim of ingesting the boundary layer is to reenergize the slower air moving near the surface of the body to reduce the drag due to friction.…”

Section: Introductionmentioning

confidence: 99%

Effect of a fuselage boundary layer ingesting propulsor on airframe forces and moments

Fernández

Smith

2020

Aerospace Science and Technology

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The aim of this research project was to investigate the benefits of hybrid-distributed propulsion and boundary layer ingestion applied to an airliner similar in size, range and cruise velocity to an Airbus A320 or a Boeing 737-800. The power system selected consisted of two under-wing mounted conventional turbofans and an electrically driven boundary layer ingesting fan, located at the rear fuselage. The power required for the fan is extracted from both turbofans. The worked carried out and presented in this paper offers a new approach to modelling boundary layer ingestion configurations, consisting of using the sliding mesh method to simulate the rotation of the blades within the airflow. The simulations indicate that ingesting the boundary layer results in remarkable improvements reducing drag and increasing propulsive force, reaffirming the potential of this technology to reduce fuel consumption. However, the results also registered large changes in the pressure distribution, and hence in the pitching, rolling and yawing moment that need to be accounted for in the design phase.

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Method for simulating the performance of a boundary layer ingesting propulsion system at design and off-design

Cited by 21 publications

References 11 publications

Propulsion system integration for a first-generation hydrogen civil airliner?

Propulsion system integration for a first-generation hydrogen civil airliner?

Power Fan Design of Blended-Wing-Body Aircraft with Distributed Propulsion System

Effect of a fuselage boundary layer ingesting propulsor on airframe forces and moments

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