Heat release rate fluctuations are the source of combustion instabilities that cause recurrent problems in many combustors. These quantities are difficult to measure and optical techniques are generally implemented. The initial validation of an alternative method is presented in the case of pulsated laminar premixed flames. The technique relies on determining the travel time of ultrasonic waves propagating through the flow. The link between heat release rate fluctuations and perturbations in the travel time of ultrasonic waves is established. Measurements made with this method are compared with optical measurements and an analytical model. A good agreement is obtained for...
The acoustic power of an oscillating flame is measured. A turbulent premixed propane/air flame is si...
Abstract: A confined premixed turbulent flame that oscillates behind a bluff body under the influenc...
Thermo-acoustic investigations require reliable measurement techniques in hot environments for press...
International audienceThe article presents a new method to measure heat release rate disturbances fr...
International audienceHeat release rate fluctuations cause recurrent problems in many steady operati...
Heat release rate disturbances are the sources of additional thermal stresses, direct and indirect c...
The detection of the response of flames to acoustic disturbances is of importance for both laborator...
The detection of the response of flames to acoustic disturbances is of importance for both laborator...
An investigation into the response of non-premixed swirling flames to acoustic perturbations at vari...
Flame-turbulence interactions are at the heart of modern combustion research as they have a major in...
Thermo-acoustic instabilities remain problematic in the design of propulsion systems such as gas tur...
International audienceThe present study focuses on a time-domain approach for investigating the resp...
The response of three flames with different degrees of premixedness (fully premixed, non-premixed wi...
The acoustic power of an oscillating flame is measured. A turbulent premixed propane/air flame is si...
This paper presents the results of a theoretical study of the interactions between a laminar, premix...
The acoustic power of an oscillating flame is measured. A turbulent premixed propane/air flame is si...
Abstract: A confined premixed turbulent flame that oscillates behind a bluff body under the influenc...
Thermo-acoustic investigations require reliable measurement techniques in hot environments for press...
International audienceThe article presents a new method to measure heat release rate disturbances fr...
International audienceHeat release rate fluctuations cause recurrent problems in many steady operati...
Heat release rate disturbances are the sources of additional thermal stresses, direct and indirect c...
The detection of the response of flames to acoustic disturbances is of importance for both laborator...
The detection of the response of flames to acoustic disturbances is of importance for both laborator...
An investigation into the response of non-premixed swirling flames to acoustic perturbations at vari...
Flame-turbulence interactions are at the heart of modern combustion research as they have a major in...
Thermo-acoustic instabilities remain problematic in the design of propulsion systems such as gas tur...
International audienceThe present study focuses on a time-domain approach for investigating the resp...
The response of three flames with different degrees of premixedness (fully premixed, non-premixed wi...
The acoustic power of an oscillating flame is measured. A turbulent premixed propane/air flame is si...
This paper presents the results of a theoretical study of the interactions between a laminar, premix...
The acoustic power of an oscillating flame is measured. A turbulent premixed propane/air flame is si...
Abstract: A confined premixed turbulent flame that oscillates behind a bluff body under the influenc...
Thermo-acoustic investigations require reliable measurement techniques in hot environments for press...