This paper presents experimental data on investigation of novel flameless combustors in

application of gas turbine engines at atmospheric conditions. Flameless combustion is

characterized by distributed flame and even temperature distribution under the conditions

of high preheat air temperature and sufficient large amount of recirculating low oxygen

concentration exhaust gas. Extremely low emissions of NOx, CO, and UHC are reported in

this paper for flameless combustion in a multiple jets premixed gas turbine combustor and a

swirling jet combustor. Measurements on the flame chemiluminescence, CO and NOx

emissions, acoustic pressure, temperature field, and velocity field reveal the influence of

preheat temperature, inlet air mass flow rate, combustor exhaust nozzle contraction ratio,

and combustor chamber diameter on emissions and combustion dynamics. The data indicate

that greater air mass flow rate, thus larger pressure drop, promotes the formation of

flameless combustion and lower NOx emissions for the same flame temperature. This

flameless combustor is in nature a premixed combustion which NOx emission is an

exponential function of the flame temperature regardless of different preheated

temperature. High preheated temperature and flow rate also helps in forming stable

combustion therefore are favorable for flameless combustion. The effects on emissions and

combustion dynamics from the combustor exhaust contraction and the combustion chamber diameter are also discussed.