Work focussed on a large number of preliminary studies of supersonic combustion in a simple combustion duct - thrust nozzle combination, investigating effects of Mach number, equivalence ratio, combustor divergence, fuel injecting angle and other parameters with an influence on the combustion process. This phase lasted for some three or four years, during which strongest emphasis was placed on responding to the request for preliminary experimental information on high enthalpy effects, to support the technology maturation activities of the NASP program. As the need for preliminary data became less urgent, it was possible to conduct more systematic studies of high enthalpy combustion phenomena, and to initiate other projects aimed at improving the facilities and instrumentation used for studying scramjet phenomena at high enthalpies. The combustion studies were particularly directed towards hypersonic combustion, and to the effects of injecting fuel along the combustion chamber wall. A substantial effort was directed towards a study of the effect of scale on the supersonic combustion process. The influence of wave phenomena (both compression waves and expansion waves) on the realization of thrust from a supersonic combustion process was also investigated. The effect of chemical kinetics was looked into, particularly as it affected the composition of the test flow provided by a ground facility. The effect of injection of the fuel through wall orifices was compared with injection from a strut spanning the stream, and the effect of heating the fuel prior to injection was investigated. Studies of fuel-air mixing by shock impingement were also done, as well as mass spectrometer surveys of a combustion wake. The use of hypersonic nozzles with an expansion tube was investigated. A new method was developed for measuring the forces acting of a model in less than one millisecond. Also included in this report are listings of published journal papers and conference presentations.
[1]
J. R. Moselle,et al.
Computer program for the numerical solution of nonequilibrium expansions of reacting gas mixtures
,
1966
.
[2]
G. T. Carson.
Analytical chemical kinetic investigation of the effects of oxygen, hydrogen, and hydroxyl radicals on hydrogen-air combustion
,
1974
.
[3]
W. J. Little,et al.
MOLLIER DIAGRAM FOR AIR
,
1963
.
[4]
Richard G. Morgan,et al.
Wave Processes in Scramjet Thrust Generation
,
1988
.
[5]
Charles K. Westbrook.
Chemical kinetic modeling of higher hydrocarbon fuels
,
1986
.
[6]
B. Mcbride,et al.
THERMODYNAMIC PROPERTIES TO 6000 K FOR 210 SUBSTANCES INVOLVING THE FIRST 18 ELEMENTS
,
1963
.
[7]
Allan Paull,et al.
High Reynolds number heat transfer to the cold walls of a model scramjet
,
1987
.
[8]
Richard G. Morgan,et al.
INFRARED SCANNING IN TRANSIENT WIND TUNNELS.
,
1985
.
[9]
Charles K. Westbrook,et al.
Chemical kinetics and modeling of combustion processes
,
1981
.
[10]
Allan Paull,et al.
Hydrogen scramjet with sidewall injection - Shock tunnel simulations
,
1987
.
[11]
R. G. Morgan,et al.
Pressure scaling effects in a scramjet combustion chamber
,
1987
.
[12]
A. G. Mclain,et al.
A hybrid computer program for rapidly solving flowing or static chemical kinetic problems involving many chemical species
,
1976
.
[13]
J. M. Simmons,et al.
Design of three-dimensional scramjet inlets for hypersonic propulsion
,
1986
.
[14]
Richard G. Morgan,et al.
Shock tunnel measurements of heat transfer in a model scramjet
,
1986
.
[15]
Richard G. Morgan,et al.
Fast Acting Hydrogen Valve
,
1983
.
[16]
Allan Paull,et al.
Scramjet sidewall burning: Preliminary shock tunnel results
,
1985
.
[17]
V. J. Scullin,et al.
General chemical kinetics computer program for static and flow reactions, with application to combustion and shock-tube kinetics
,
1972
.