Detonation wave compression in gas turbines

A study was made of the concept of augmenting the performance of low pressure ratio gas turbines by detonation wave compression of part of the flow. The concept exploits the constant volume heat release of detonation waves to increase the efficiency of the Brayton cycle. In the models studied, a fraction of the compressor output was channeled into detonation ducts where it was processed by transient transverse detonation waves. Gas dynamic studies determined the maximum cycling frequency of detonation ducts, proved that upstream propagation of pressure pulses represented no problems and determined the variations of detonation duct output with time. Mixing and wave compression were used to recombine the combustor and detonation duct flows and a concept for a spiral collector to further smooth the pressure and temperature pulses was presented as an optional component. The best performance was obtained with a single firing of the ducts so that the flow could be re-established before the next detonation was initiated. At the optimum conditions of maximum frequency of the detonation ducts, the gas turbine efficiency was found to be 45 percent while that of a corresponding pressure ratio 5 conventional gas turbine was only 26%. Comparable improvements in specific fuel consumption data were found for gas turbines operating as jet engines, turbofans, and shaft output machines. Direct use of the detonation duct output for jet propulsion proved unsatisfactory. Careful analysis of the models of the fluid flow phenomena led to the conclusion that even more elaborate calculations would not diminish the uncertainties in the analysis of the system. Feasibility of the concept to work as an engine now requires validation in an engineering laboratory experiment

School Safety Planning: A Survey of Bond, Fayette and Effingham County Schools

This study was designed to assess the readiness of Illinois public and parochial schools in Bond, Fayette and Effingham Counties to implement school policies, building security strategies, and violence prevention/intervention programs to improve school safety. The study examined current trends in the school safety planning of the respondents. In addition, the study examined the relationship between the schools\u27 implementation of violence prevention/intervention programs and their use of safety grants, the relationship between the array of safety measures implemented by the responding schools and their involvement of school and community groups in their planning, and the relationship between the array of safety measures implemented by the responding schools and the number of different types of violent incidents those school experienced. School policies were given the greatest emphasis in safety planning by the responding schools, followed by violence prevention/intervention programs, and building security strategies. No significant relationships were found for the following: the schools\u27 implementation of violence prevention/intervention programs and their use of safety grants; the schools\u27 implementation of a broad array of safety measures and their involvement of school and community groups in safety planning; and the schools\u27 implementation of a broad array of safety measures and the number of different types of violent incidents those schools experienced

Chemical and kinetic equilibrations via radiative parton transport

A hot and dense partonic system can be produced in the early stage of a relativistic heavy ion collision. How it equilibrates is important for the extraction of Quark-Gluon Plasma properties. We study the chemical and kinetic equilibrations of the Quark-Gluon Plasma using a radiative transport model. Thermal and Color-Glass-Condensate motivated initial conditions are used. We observe that screened parton interactions always lead to partial pressure isotropization. Different initial pressure anisotropies result in the same asymptotic evolution. Comparison of evolutions with and without radiative processes shows that chemical equilibration interacts with kinetic equilibration and radiative processes can contribute significantly to pressure isotropization.Comment: Presented at 24th International Nuclear Physics Conference (INPC2010), Vancouver, Canada, 4-9 July 201

Study of the use of Metal-Oxide-Silicon (MOS) devices for particulate detection and monitoring in the earth's atmosphere

A metal-oxide-silicon (MOS) capacitor-type particulate sensor was evaluated for use in atmospheric measurements. An accelerator system was designed and tested for the purpose of providing the necessary energy to trigger the MOS-type sensor. The accelerator system and the MOS sensor were characterized as a function of particle size and velocity. Diamond particles were used as particulate sources in laboratory tests. Preliminary tests were performed in which the detector was mounted on an aircraft and flown in the vicinity of coal-fired electric generating plants