Mechanisms and performance of coal burning Rijke type pulsating combustors

Wang, Muh-Rong

05 1900

No description available.

Coal Combustion

Coal combustion in precessing jet flames / by Nikolaos Pandelis Megalos.

Megalos, Nikolaos Pandelis

January 1998

Bibliography: leaves 369-382. / xxi, 382 leaves : ill. ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Examines the potential of the PJ nozzle in the low NOx combustion of coal and is primarily concerned with application to cement kilns. / Thesis (Ph.D.)--University of Adelaide, Dept. of Chemical Engineering, 1998

Coal Combustion.

PREDICTION OF PARTICLE TRAJECTORIES IN OPPOSED FLOW FIELDS.

Masteller, Melissa Mae.

January 1984

No description available.

Coal -- Combustion.

Particles.

The control of fluidised combustors

Gray, D. T.

January 1986

No description available.

621.43

Fluidised coal combustion

The hydrodynamics of circulating fluidized beds

Harris, Benjamin James

January 1992

No description available.

532

Coal combustion

AN EXPERIMENTAL STUDY OF COAL PYROLYSIS IN FLAT, LAMINAR OPPOSED FLOW COMBUSTION CONFIGURATIONS.

Kram, Brian Howard.

January 1984

No description available.

Coal -- Combustion.

Pyrolysis.

The monitoring of near burner slag formation

Tan, Chee Keong

January 2002

No description available.

662

Pulverised coal combustion

The formation and monitoring of gases associated with the spontaneous combustion of coal

Cooper, Malcolm

January 1991

No description available.

621.43

Coal combustion chemistry

Pyrolysis of Fine Coal Particles at High Heating Rate and Pressure

Mill, Christopher John, School of Chemical Engineering & Industrial Chemistry, UNSW

January 2000

High-intensity pyrolysis, rapid heating in an inert gas atmosphere at up to 20 atm pressure, of 6 Australian coals was examined to gain further insight into high-intensity processes such as Integrated Gasification Combined Cycles (IGCC). Experiments focussed on pyrolysis in a specially developed Wire Mesh Reactor (WMR). The particle temperature lagged that of the mesh by 0.2 seconds at a heating rate of 100??~C s -1 and was predicted by modelling. This is part of the reason the volatile yield (VY) results for 10 s hold-time at ???b1.7 wt% daf of coal, is much more reproducible than 1 s hold-time experiments at ???b4.2 wt% daf of coal. Four coals of the same rank did not behave identically when heated. Three of the coals had a pyrolysis VY the same as the proximate VM when heated to 100??~C at 1 atm but the fourth, higher inertinite coal had a 1 atm pyrolysis VY 90% of its proximate VM. All four coals of similar rank had a significant decrease in VY, between 10 and 20 wt% daf of coal, with pressure increasing from 1 to 20 atm. The two lower rank coals showed less decrease in VY with increasing pressure than the higher rank and higher inertinite coals. The lower decrease in VY with increased pressure was mostly attributed to the lower inertinite levels for both the coals of similar rank and VM, and the coals of lower rank. Char characteristics examined focussed on pore Surface Area (SA). For high intensity WMR and Drop Tube Furnace (DTF) pyrolysis experiments CO2 SA for char from a particular coal was similar but the BET SA different. This was due to the char in the WMR experiments having longer to form larger pores determined by BET N2 SA. Both the N2 and CO2 SA was more than an order of magnitude greater than for low intensity pyrolysis char. This highlights that the WMR can be used to attain char with similar CO2 SA characteristics as other high intensity pyrolysis experiments and to provide a more meaningful insight into char reactivity than low intensity chars do.

Coal Combustion

Pyrolysis

Ignition and combustion of pulverized coal particles injected by an opposed jet to a flat flame burner

Nguyen, Luan Hoang

08 1900

No description available.

Coal Combustion

Gas-burners