Author: Reid Thompson MilnerPublisher:
ISBN:
Category :
Languages : en
Pages : 84
Book Description
Studies in the Oxidation of Coal Oxygen and Hydrogen Oxidation
Author: Reid Thompson MilnerStudies in the Oxidation of Certain Coals with Molecular Oxygen
Author: David George GiddingsI. Comparatives Studies in the Ozonolysis of Lignin and Coal
Author: Marvinton SweenyNatural Oxidation of Coal
Author: Robert M. DavidsonPublisher:
ISBN:
Category : Coal
Languages : en
Pages : 84
Book Description
Electrochemical Oxidation of Alberta Coals in New Environments
Author: Birss, V. IPublisher: The Office
ISBN:
Category : Coal
Languages : en
Pages : 58
Book Description
The Oxidation of Hydrogen, Carbon Monoxide and the Paraffin Hydrocarbons by Copper Oxide
Author: James Grieve KingPublisher:
ISBN:
Category : Alkanes
Languages : en
Pages : 38
Book Description
Coal Combustion by Wet Oxidation
Author: Publisher:
ISBN:
Category :
Languages : en
Pages :
Book Description
The combustion of coal by wet oxidation was studied by the Center for Waste Management Programs, of Michigan Technological University. In wet oxidation a combustible material, such as coal, is reacted with oxygen in the presence of liquid water. The reaction is typically carried out in the range of 204/sup 0/C (400/sup 0/F) to 353/sup 0/C (650/sup 0/F) with sufficient pressure to maintain the water present in the liquid state, and provide the partial pressure of oxygen in the gas phase necessary to carry out the reaction. Experimental studies to explore the key reaction parameters of temperature, time, oxidant, catalyst, coal type, and mesh size were conducted by running batch tests in a one-gallon stirred autoclave. The factors exhibiting the greatest effect on the extent of reaction were temperature and residence time. The effect of temperature was studied from 204/sup 0/C (400/sup 0/F) to 260/sup 0/C (500/sup 0/F) with a residence time from 600 to 3600 seconds. From this data, the reaction activation energy of 2.7 x 10/sup 4/ calories per mole was determined for a high-volatile-A-Bituminous type coal. The reaction rate constant may be determined at any temperature from the activation energy using the Arrhenius equation. Additional data were generated on the effect of mesh size and different coal types. A sample of peat was also tested. Two catalysts were evaluated, and their effects on reaction rate presented in the report. In addition to the high temperature combustion, low temperature desulfurization is discussed. Desulfurization can improve low grade coal to be used in conventional combustion methods. It was found that 90% of the sulfur can be removed from the coal by wet oxidation with the carbon untouched. Further desulfurization studies are indicated.
Studies of Coal Oxidation Using Ion Microscopy and X-ray Photoelectron Spectroscopy, Phase III
Author: Publisher:
ISBN:
Category :
Languages : en
Pages : 91
Book Description
Report on the oxidation of coal using two surface-sensitive spectroscopic techniques: Secondary Ion Mass Spectrometry (SIMS) and X-ray Photoelectron Spectroscopy (XPS). This report focuses on aspects of coal surface chemistry which can lead to increased intake of oxygen. This has been studied using isotopically-labelled oxygen as well as specific reagent groups which react uniquely with certain chemical sites on a surface. SIMS imaging was used to identify specific microscopic regions of the coal where reactions occurred, and to correlate the interaction of surface regions containing different elements or functional goups and XPS chemical shifts were used to follow the chemistry of carbon, sulphur, oxygen, iron and other elements as a function of oxidation.
Oxidation of Anthracite with Concentrated Nitric Acid
Author: M. A. HammerPublisher:
ISBN:
Category : Anthracite coal
Languages : en
Pages : 26
Book Description
Characterization of Early Stage Coal Oxidation and Effects of Drying and Supercritical CO2 Pretreatment on Chemical Structure of Coals
Author: Guang ShiPublisher:
ISBN:
Category :
Languages : en
Pages : 364
Book Description
To obtain representative temperature-programmed desorption (TPD) profiles of young oxidized chars up to 1650°C with minimal reactor wall interferences, the chemistry and physics of four ceramic materials has been critically reviewed. A two-staged experimental apparatus is then uniquely designed to produce chars in an Al 2 O 3 flow reactor with 1 to 21% O 2 followed by in-situ TPD with a SiC tube. Comparison of TPD profiles of oxidized chars with those from pyrolyzed chars and ashes suggests early stage char oxidation is profoundly influenced by oxygen from three sources: organics oxygen, mineral matters and gas phase O 2 . Young chars oxidized at 1000°C with less than 0.3 s residence time shows CO desorption peaks during TPD at three distinct temperatures: 730, 1280, and 1560°C. The peaks at 730°C are mainly caused by incomplete devolatilization. The peaks at 1280°C represent mainly desorption of stable surface oxides and incomplete devolatilization. Increasing the gas phase oxidants notably increases the amount of stable surface oxides. The broad peaks between 1400 and 1650°C are attributed to the reactions of oxidants decomposed from minerals and carbon in the char or SiC tube. Gas-phase oxygen shifts these reactions to lower temperatures. Detailed oxygen balance based on the CO and CO 2 yields and elemental compositions of both pyrolysis and oxidized chars reveals that oxygen uptakes are very high, +0.056 mg O per mg of carbon, in chars derived from bituminous coal, while lignite chars show negative oxygen uptake, -0.020 mg O per mg of carbon, in char. Indeed, lignite char seems to possess little amount of stable surface oxides other than those contributed by the minerals. The extensive emissions of CO from lignite chars during TPD seem to suggest that either O 2 or minerals promotes the oxygen transfer on char surface and subsequent carbon oxidation. The studies on the ignition, devolatilization and combustion kinetics of chars in oxy-coal combustion reflect the fundamental importance of oxidant-activated mechanisms in the early stage of char oxidation. Independently, temperature-programmed desorption (TPD) has revealed sensitive characteristics of chars oxidized by 1-21% O 2 . It demonstrated the existence of stable surface oxides that desorb between 1100-1650°C. Interactions between CO 2 and coal have been gaining interests due to its application in geologic sequestration of CO 2 and methane recovery in coalmines. Recently, we reported the changes in combustion behaviors, including NO emissions and carbon burnout, and physical structures of coals after treatment. The objective of the third part of my work is to investigate the changes in chemical structure of coals after supercritical CO 2 treatment. We found that drying and pretreatment can alter the CO and CO 2 emissions during coal pyrolysis. FTIR analysis shows that oxygen functional groups were found to be significantly changed after drying and/or pretreatment by supercritical CO 2 for both bituminous coal and lignite. These phenomena may significantly affect the conversion of coal gasification and liquefaction.