Influence Factors for Impact Actions and Transient Trajectories of Fan Blades after Fan Blade Out in Typical 2-Shaft High Bypass Ratio Turbofan Engine

Ultra-high bypass ratio (UHBR) engines are designed as compact as possible and are characterized by a short asymmetric air inlet and heterogeneous outlet guide vanes (OGVs). The flow close to the fan is therefore circumferentially nonuniform (or distorted) and the resulting noise might be impacted. This is studied here at take-off conditions by means of a simulation of the unsteady Reynolds-averaged Navier–Stokes (URANS) equations of a full-annulus fan stage. The model includes an asymmetric air inlet, a fan, heterogeneous OGVs, and homogeneous inlet guide vanes (IGVs). Direct acoustic predictions are given for both inlet and aft noises. A novel hydrodynamic/acoustic splitting method based on a modal decomposition is developed and is applied for the aft noise analysis. The noise mechanisms that are generally considered (i.e., interaction of fan-blade wakes with OGVs and fan self-noise) are shown to be impacted by the distortion. In addition, new sources caused by the interaction between the stationary distortion and the fan blades appear and contribute to the inlet noise.

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Numerical Study of the Fan Blades Design and Operating Parameters for a High Bypass Ratio Engine

Volume 2C: Turbomachinery ◽

10.1115/gt2020-14425 ◽

2020 ◽

Author(s):

Huoxing Liu ◽

Zhongfu Tang ◽

Igor Shirokov

Keyword(s):

Numerical Study ◽

High Mass ◽

Civil Aviation ◽

Operating Parameters ◽

Outlet Section ◽

Inlet Section ◽

Turbofan Engine ◽

The Future ◽

Fan Blade ◽

Bypass Ratio

Abstract High bypass ratio turbofan engine is the dominant side of civil aviation engines market at present. This trendency will not change in the coming decades. In a turbofan engine with high thrust, high mass flow and high bypass ratio, the fan blade is the key component. But most investigations only focus on the individual part design and validation. As the multi-disciplines coupling research are more and more important. The systemlevel research will be an important investigation trend in the future. The purpose of this paper is the source design of the fan blade, which starts from the aircraft requirement and consists of the turbomachine design and operating parameters design. The main research area is from the inlet section of the engine to the outlet section of the fan rotor (single stage). So, different from the traditional axial compressor design, this paper also considers the overall operating parameters of the engine and organically combines the fan design with the overall engine design by the aerothermodynamic analysis. Based on the partial data of fan components of Russian PD-20 engine, The process, which consist of the overall performance design of the engine, fan components performance design, fan aerodynamic design and modeling, CFD method, flow field mechanism analysis, fluid-solid coupling, are formed into a simply systematical design of the fan blade. All the work except the CFD solver are programmed for the future research in propulsion system.

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Feasibility Study of Some Novel Concepts for High Bypass Ratio Turbofan Engines

Volume 1: Aircraft Engine; Ceramics; Coal, Biomass and Alternative Fuels; Controls, Diagnostics and Instrumentation; Education; Electric Power; Awards and Honors ◽

10.1115/gt2009-59166 ◽

2009 ◽

Cited By ~ 1

Author(s):

Dipanjay Dewanji ◽

G. Arvind Rao ◽

Jos van Buijtenen

Keyword(s):

Fuel Consumption ◽

Substantial Reduction ◽

Substantial Improvement ◽

Fuel Price ◽

Turbofan Engine ◽

Turbofan Engines ◽

Fuel Flow ◽

Blade Tip ◽

Fan Blade ◽

Bypass Ratio

The soaring fuel price and the burgeoning environmental concerns have compelled global research towards cleaner engines, aimed at substantial reduction in emission, noise and fuel consumption. In this context, the present research investigates the feasibility of some novel engine concepts, namely Geared Turbofan and Intercooled Recuperated Turbofan concepts, by hypothetically applying them into an existing state-of-the-art high bypass ratio engine. This paper made an effort to estimate the effects on the baseline engine performances due to the introduction of these two concepts into it. By performing steady state simulations, it was found that the incorporation of the Geared Turbofan concept into the existing Turbofan engine caused a significant reduction in thrust specific fuel consumption, engine weight, and fan blade tip speed. However, when simulations were also carried out by incorporating the Intercooler and Recuperator concept in the baseline turbofan engine, it did not demonstrate any substantial improvement in fuel consumption. It was observed that the fuel flow rate was influenced to a large extent by heat exchanger’s effectiveness and the pressure drop within it. The overall engine weight was also found to get increased due to the inclusion of massive heat exchangers necessary for the system.

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THREE-DIMENSIONAL FLOW IN A TRANSONIC AXIAL FLOW FAN OF A HIGH BYPASS RATIO TURBOFAN ENGINE

International Conference on Aerospace Sciences and Aviation Technology ◽

10.21608/asat.2011.27139 ◽

2011 ◽

Vol 11 (ASAT CONFERENCE) ◽

pp. 1-21

Author(s):

A. ABD EL-AZIM ◽

M. GOBRAN ◽

H. HASSAN

Keyword(s):

Three Dimensional ◽

Axial Flow ◽

Axial Flow Fan ◽

Three Dimensional Flow ◽

Turbofan Engine ◽

Dimensional Flow ◽

Bypass Ratio

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A Comparative Study of Genetic Algorithms and Gradient Methods for RM12 Turbofan Engine Diagnostics and Performance Estimation

Volume 2: Turbo Expo 2004 ◽

10.1115/gt2004-53591 ◽

2004 ◽

Cited By ~ 7

Author(s):

Tomas Gro¨nstedt ◽

Markus Wallin

Keyword(s):

Gas Turbine ◽

Performance Test ◽

Gradient Methods ◽

Performance Testing ◽

Performance Estimation ◽

Data Sets ◽

Data Set ◽

Turbofan Engine ◽

Local Optima ◽

Bypass Ratio

Recent work on gas turbine diagnostics based on optimisation techniques advocates two different approaches: 1) Stochastic optimisation, including Genetic Algorithm techniques, for its robustness when optimising objective functions with many local optima and 2) Gradient based methods mainly for their computational efficiency. For smooth and single optimum functions, gradient methods are known to provide superior numerical performance. This paper addresses the key issue for method selection, i.e. whether multiple local optima may occur when the optimisation approach is applied to real engine testing. Two performance test data sets for the RM12 low bypass ratio turbofan engine, powering the Swedish Fighter Gripen, have been analysed. One set of data was recorded during performance testing of a highly degraded engine. This engine has been subjected to Accelerated Mission Testing (AMT) cycles corresponding to more than 4000 hours of run time. The other data set was recorded for a development engine with less than 200 hours of operation. The search for multiple optima was performed starting from more than 100 extreme points. Not a single case of multi-modality was encountered, i.e. one unique solution for each of the two data sets was consistently obtained. The RM12 engine cycle is typical for a modern fighter engine, implying that the obtained results can be transferred to, at least, most low bypass ratio turbofan engines. The paper goes on to describe the numerical difficulties that had to be resolved to obtain efficient and robust performance by the gradient solvers. Ill conditioning and noise may, as illustrated on a model problem, introduce local optima without a correspondence in the gas turbine physics. Numerical methods exploiting the special problem structure represented by a non-linear least squares formulation is given special attention. Finally, a mixed norm allowing for both robustness and numerical efficiency is suggested.

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Design and Analysis of an Aircraft Thermal Management System Linked to a Low-Bypass Ratio Turbofan Engine

10.1115/gt2021-58942 ◽

2021 ◽

Author(s):

Robert A. Clark ◽

Mingxuan Shi ◽

Jonathan Gladin ◽

Dimitri Mavris

Keyword(s):

Thermal Management ◽

Management System ◽

Environmental Control ◽

Cooling System ◽

Heat Transfer Fluid ◽

Turbofan Engine ◽

Thermal Management System ◽

Air Stream ◽

The Impact ◽

Bypass Ratio

Abstract The design of an aircraft thermal management system (TMS) that is capable of rejecting heat loads into the bypass stream of a typical low-bypass ratio turbofan engine, or a ram-air stream, is investigated. The TMS consists of an air cycle system (ACS), which is similar to the typical air cycle machines (ACMs) used on current aircraft, both military and commercial. This system turbocharges compressor bleed air and uses heat exchangers in a ram air stream or the engine bypass stream to cool the engine bleed air prior to expanding it to low temperatures suitable for heat rejection. In this study, a simple low-bypass ratio afterburning turbofan engine was modeled in NPSS to provide boundary conditions to the TMS system throughout the flight envelope of a typical military fighter aircraft. The engine was sized to produce sea level static (SLS) thrust roughly equivalent to that of an F-35-class engine. Two different variations of the TMS system, a ram air cooled and a bypass air cooled, were sized to handle a given demanded aircraft heat load, which might include environmental control system (ECS) loads, avionics cooling loads, weapons system loads, or other miscellaneous loads. The architecture and modeling of the TMS is described in detail, and the ability of the sized TMS to reject these demanded aircraft loads throughout several key off-design points was analyzed, along with the impact of ACS engine bleeds on engine thrust and fuel consumption. A comparison is made between the cooling capabilities of the ram-air stream versus the engine bypass stream, along with the benefits and drawbacks of each cooling stream. It is observed that the maximum load dissipation capability of the TMS is tied directly to the amount of engine bleed flow, while the level of bleed flow required is set by the temperature conditions imposed by the aircraft cooling system and the heat transfer fluid used in the ACS thermal transport bus. Furthermore, the higher bypass stream temperatures significantly limit the thermodynamic viability and capability of a TMS designed with bypass air as the ultimate heat sink. The results demonstrate the advantage that adaptive, variable cycle engines (VCEs) may have for future military aircraft designs, as they combine the best features of the two TMS architectures that were studied here.

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Design and Analysis of an Aircraft Thermal Management System Linked to a Low Bypass Ratio Turbofan Engine

Journal of Engineering for Gas Turbines and Power ◽

10.1115/1.4052031 ◽

2021 ◽

Author(s):

Robert Clark ◽

Mingxuan Shi ◽

Jonathan Gladin ◽

Dimitri N. Mavris

Keyword(s):

Thermal Management ◽

Management System ◽

Cooling System ◽

Maximum Load ◽

Fighter Aircraft ◽

Turbofan Engine ◽

Cycle System ◽

Thermal Management System ◽

Air Stream ◽

Bypass Ratio

Abstract The design of an aircraft thermal management system (TMS) that is capable of rejecting heat loads into the bypass stream of a typical low-bypass ratio turbofan engine, or a ram-air stream, is investigated. The TMS consists of an air cycle system, similar to the typical air cycle machines used on current aircraft, both military and commercial. This system turbocharges compressor bleed air and uses heat exchangers in a ram air stream, or the engine bypass stream, to cool the engine bleed air prior to expanding it to low temperatures suitable for heat rejection. In this study, a simple low-bypass ratio afterburning turbofan engine was modeled in NPSS to provide boundary conditions to the TMS system throughout the flight envelope of a typical military fighter aircraft. Two variations of the TMS system, a ram air cooled and a bypass air cooled, were sized to handle a given demanded aircraft heat load. The ability of the sized TMS to reject the demanded aircraft load throughout several key off-design points was analyzed. It was observed that the maximum load dissipation capability of the TMS is tied to the amount of engine bleed flow, while the level of bleed flow required is set by the temperature conditions imposed by the aircraft cooling system. Notably, engine bypass stream temperatures significantly limit the thermodynamic viability of a TMS designed with bypass air as the heat sink. The results demonstrate the advantage that variable cycle engines may have for future aircraft designs.

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