EXPERIMENTAL INVESTIGATION OF SHOCK TRANSFER AND SHOCK INITIATED DETONATION IN A DUAL PULSE DETONATION ENGINE CROSSOVER SYSTEM

Driscoll, Robert B.

21 October 2013

No description available.

Aerospace Materials

Pulse Detonation Engine

Detonation

Crossover

A NUMERICAL STUDY OF DETONATION AND PLUME DYNAMICS IN A PULSED DETONATION ENGINE

RAGHUPATHY, ARUN PRAKASH

28 September 2005

No description available.

Engineering, Aerospace

Pulse Detonation Engine

Chemical Kinetics

Detonation Modeling

Combustion

Direct-connect performance evaluation of a valveless pulse detonation engine

Wittmers, Nicole K.

12 1900

Approved for public release, distribution is unlimited / Operational characteristics of a valveless pulse detonation engine system were characterized by experimental measurements of thrust, fuel flow, and internal gas dynamics. The multi-cycle detonation experiments were performed on an axis-symmetric engine geometry operating on an ethylene/air mixtures. The detonation diffraction process from a small 'initiator' combustor to a larger diameter main combustor in a continuous airflow configuration was evaluated during multi-cycle operation of a pulse detonation engine and was found to be very successful at initiating combustion of the secondary fuel/air mixture at high frequencies. The configuration was used to demonstrate the benefit of generating an overdriven detonation condition near the diffraction plane for enhanced transmission of the larger combustor. Results have shown that the addition of optical sensors, such as tunable diode lasers, to provide fuel profile data are invaluable for providing high fidelity performance results. The performance results demonstrated the ability of the valveless pulse detonation engine to run at efficiencies similar to valved pulse detonation engine geometries and may be a low cost alternative to conventional air-breathing propulsion systems. / Funded By: N00014OWR20226. / Lieutenant, United States Navy

Detonation waves

Combustion

Airplanes

Motors

Thrust

Pulse detonation engine

Supersonic air breathing

Engine performance evaluation

Numerical modelling of pressure rise combustion for reducing emissions of future civil aircraft

Materano Blanco, Gilberto Ignacio

January 2014

This work assesses the feasibility of designing and implementing the wave rotor (WR), the pulse detonation engine (PDE) and the internal combustion wave rotor (ICWR) as part of novel Brayton cycles able to reduce emissions of future aircraft. The design and evaluation processes are performed using the simplified analytical solution of the devices as well as 1D-CFD models. A code based on the finite volume method is built to predict the position and dimensions of the slots for the WR and ICWR. The mass and momentum equations are coupled through a modified SIMPLE algorithm to model compressible flow. The code includes a novel tracking technique to ensure the global mass balance. A code based on the method of characteristics is built to predict the profiles of temperature, pressure and velocity at the discharge of the PDE and the effect of the PDEs array when it operates as combustion chamber of gas turbines. The detonation is modelled by using the NASA-CEA code as a subroutine whilst the method of characteristics incorporates a model to capture the throttling and non-throttling conditions obtained at the PDE's open end during the transient process. A medium-sized engine for business jets is selected to perform the evaluation that includes parameters such as specific thrust, specific fuel consumption and efficiency of energy conversion. The ICWR offers the best performance followed by the PDE; both options operate with a low specific fuel consumption and higher specific thrust. The detonation in an ICWR does not require an external source of energy, but the PDE array designed is simple. The WR produced an increase in the turbine performance, but not as high as the other two devices. These results enable the statement that a pressure rise combustion process behaves better than pressure exchangers for this size of gas turbine. Further attention must be given to the NOx emission, since the detonation process is able to cause temperatures above 2000 K while dilution air could be an important source of oxygen.

629.134

Numerical modelling of pressure rise combustion for reducing emissions of future civil aircraft

Materano Blanco, Gilberto Ignacio

04 1900

This work assesses the feasibility of designing and implementing the wave rotor (WR), the pulse detonation engine (PDE) and the internal combustion wave rotor (ICWR) as part of novel Brayton cycles able to reduce emissions of future aircraft. The design and evaluation processes are performed using the simplified analytical solution of the devices as well as 1D-CFD models. A code based on the finite volume method is built to predict the position and dimensions of the slots for the WR and ICWR. The mass and momentum equations are coupled through a modified SIMPLE algorithm to model compressible flow. The code includes a novel tracking technique to ensure the global mass balance. A code based on the method of characteristics is built to predict the profiles of temperature, pressure and velocity at the discharge of the PDE and the effect of the PDEs array when it operates as combustion chamber of gas turbines. The detonation is modelled by using the NASA-CEA code as a subroutine whilst the method of characteristics incorporates a model to capture the throttling and non-throttling conditions obtained at the PDE's open end during the transient process. A medium-sized engine for business jets is selected to perform the evaluation that includes parameters such as specific thrust, specific fuel consumption and efficiency of energy conversion. The ICWR offers the best performance followed by the PDE; both options operate with a low specific fuel consumption and higher specific thrust. The detonation in an ICWR does not require an external source of energy, but the PDE array designed is simple. The WR produced an increase in the turbine performance, but not as high as the other two devices. These results enable the statement that a pressure rise combustion process behaves better than pressure exchangers for this size of gas turbine. Further attention must be given to the NOx emission, since the detonation process is able to cause temperatures above 2000 K while dilution air could be an important source of oxygen.

Wave Rotor

Pulse Detonation Engine

Internal Combustion Wave Rotor

Gas turbine

Performance

AN EXPERIMENTAL AND COMPUTATIONAL STUDY OF PULSE DETONATION ENGINES

ALLGOOD, DANIEL CLAY

January 2004

No description available.

Engineering, Aerospace

pulse detonation engine

detonation

nozzles

ejectors

acoustics

shadowgraph

blast waves

computational fluid dynamics

chemiluminescence

Investigation of Sustained Detonation Devices: the Pulse Detonation Engine-Crossover System and the Rotating Detonation Engine System

Driscoll, Robert B.

26 May 2016

No description available.

Aerospace Materials

Detonation

Pulse Detonation Engine

Rotating Detonation Engine

PDE-Crossover System

Reactant Injection Mixing

Numerical simulations of unsteady flows in a pulse detonation engine by the conservation element and solution element method

He, Hao

13 March 2006

No description available.

Engineering, Mechanical

Detonation

Pulse Detonation Engine

The CESE Method

Computational Fluid Dynamics

Numerical Simulation

Parallel Computing

Characterization of a Rotating Detonation Engine with an Air Film Cooled Outer Body

Chriss, Scott Llewellyn

10 August 2022

No description available.

Aerospace Engineering

Mechanical Engineering

Detonation

Rotating Detonation Engine

Film Cooling

Pressure Gain Combustion

Pulse Detonation Engine

Combustion

Thermodynamics

Heat Transfer

Constant Volume Combustion

Propulsion

Propulsion Systems

Stability

Hydrogen

Thermal Management