Modeling and mode transition simulation of over-under turbine based combined cycle (TBCC) propulsion system based on inlet/engine matching
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Yuan Gao
Abstract
The over-under turbine based combined cycle (TBCC) propulsion system dynamic model is established, including the engine model and inlet model. A dual-channel inlet is designed to match the engine and the inlet performance parameters are obtained by computational fluid dynamics (CFD) calculation, which provides original data for the integrated Inlet/Engine matching model. Control plan is designed to ensure that the engine is not over-temperature, over-rotation or surging based on correlation analysis. The simulation results show that the designed control plan can keep the TBCC propulsion system continuous in thrust during the mode transition, and the thrust fluctuation is about 10%.
Funding source: National Science and Technology Major Project
Award Identifier / Grant number: 2017-V-0004-0054
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Author contribution: All the authors have accepted responsibility for the entire content of this submitted manuscript and approved submission.
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Research funding: This research is supported by National Science and Technology Major Project (2017-V-0004-0054).
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Conflict of interest statement: The authors declare no conflicts of interest regarding this article.
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© 2020 Walter de Gruyter GmbH, Berlin/Boston
Artikel in diesem Heft
- Frontmatter
- Characterization of titanium grade 5 alloy compressor blade in a jet engine using advanced materials for optimum thrust production
- Numerical investigation of total temperature distortion problem in a multistage fan based on body force approach
- Life assessment of a high temperature probe designed for performance evaluation and health monitoring of an aero gas turbine engine
- Baseline architecture design for a turboelectric distributed propulsion system using single turboshaft engine operational scenario
- Active fault tolerant control of turbofan engines with actuator faults under disturbances
- Modeling and mode transition simulation of over-under turbine based combined cycle (TBCC) propulsion system based on inlet/engine matching
- Numerical analysis of high temperature gas flow through conical micronozzle
- Simulation and analysis of an aero-engine combustor with a slinger fuel injection system
- Influence of plasma-chemical products on process stability in a low-emission gas turbine combustion chamber
- Influence of nozzle exit geometrical parameters on supersonic jet decay
- Experimental investigation on mixing characteristics of high speed co-flow jets by using tabbed chevron nozzle
- Study of a new effervescent atomizer design
Artikel in diesem Heft
- Frontmatter
- Characterization of titanium grade 5 alloy compressor blade in a jet engine using advanced materials for optimum thrust production
- Numerical investigation of total temperature distortion problem in a multistage fan based on body force approach
- Life assessment of a high temperature probe designed for performance evaluation and health monitoring of an aero gas turbine engine
- Baseline architecture design for a turboelectric distributed propulsion system using single turboshaft engine operational scenario
- Active fault tolerant control of turbofan engines with actuator faults under disturbances
- Modeling and mode transition simulation of over-under turbine based combined cycle (TBCC) propulsion system based on inlet/engine matching
- Numerical analysis of high temperature gas flow through conical micronozzle
- Simulation and analysis of an aero-engine combustor with a slinger fuel injection system
- Influence of plasma-chemical products on process stability in a low-emission gas turbine combustion chamber
- Influence of nozzle exit geometrical parameters on supersonic jet decay
- Experimental investigation on mixing characteristics of high speed co-flow jets by using tabbed chevron nozzle
- Study of a new effervescent atomizer design
