Spelling suggestions: "subject:"ferrous"" "subject:"verrous""
21 |
Metallurgical characterisation of george fisher mesotextures and microtexturesBojcevski, D. Unknown Date (has links)
No description available.
|
22 |
Modelling granular flow in caving mines: large scale physical modelling and full scale experimentsPower, G. R. Unknown Date (has links)
No description available.
|
23 |
Modelling granular flow in caving mines: large scale physical modelling and full scale experimentsPower, G. R. Unknown Date (has links)
No description available.
|
24 |
Metallurgical characterisation of george fisher mesotextures and microtexturesBojcevski, D. Unknown Date (has links)
No description available.
|
25 |
Metallurgical characterisation of george fisher mesotextures and microtexturesBojcevski, D. Unknown Date (has links)
No description available.
|
26 |
Destruction of perchlorate and nitrate by stabilized zero-valent iron nanoparticles and immobilization of mercury by a new class of iron sulfide nanoparticlesXiong, Zhong, Zhao, Dongye, January 2007 (has links) (PDF)
Thesis (Ph. D.)--Auburn University, 2007. / Abstract. Vita. Includes bibliographical references (p. 144-169).
|
27 |
Bio-oxidation of ferrous iron at low temperature conditions in a packed bed column bioreactorsChukwuchendo, Emmanuel Chukwunonso January 2016 (has links)
Thesis (MTech (Chemical Engineering))--Cape Peninsula University of Technology, 2016. / The oxidation of microbial ferrous iron is an important sub-process in the bioleaching process. Several studies focussing on microbial ferrous iron oxidation have been investigated and reported in various studies. These studies were carried out using stirred tank bioreactors and shake flasks at optimum conditions. However, these studies could not describe the context of heap bioleach system. Packed column system may describe heap bioleaching, and most studies on microbial ferrous iron oxidation were performed under flooded conditions, which do not represent solution flow dynamics in a heap situation.
Biooxidation of ferrous iron oxidation kinetics of Acidiobacillus ferrooxidans was studied in a packed-bed bioreactor to investigate the kinetics in a system that mimics the solution flow dynamic of a heap bioleach operation at low-temperature conditions. This was done in a batch mode operation, with glass marble (15 mm) as reactor packing. The pH of the bioreactor was maintained at pH 1.35 ± 0.05 and aeration at 500 ml/min. Unstructured models known as Monod and Hansford were used to describe the experimental data in determining the kinetics of bio-oxidation.
|
28 |
INTEGRATING CORROSION TESTING INDUSTRIAL PROTOCOLS INTO A HIGH SCHOOL / TWO-YEAR COLLEGE CHEMISTRY CURRICULUMD'Agostino, Michael Angelo 03 May 2005 (has links)
No description available.
|
29 |
Advances in Sintering of Powder Metallurgy SteelsKariyawasam, Nilushi Christine January 2017 (has links)
In comparison to traditionally fabricated steels that can undergo extensive processing to produce a complex-shaped component, the powder metallurgy (PM) technique can provide a more efficient approach as it is capable of producing intricately-shaped components that require little to no additional processing and machining [1], [2]. A key factor in being able to do so pertains to quenching and utilizing an appropriate quenching agent that can provide dimensional stability to the part being quenched [3], [4]. To ensure that a PM component can perform equally well when being quenched by a quenchant of reduced cooling capability, the PM component should be if not more, then just as hardenable. Steel hardenability can inevitably be improved with the increase of overall alloying content [5], however, if overall alloying content is to be kept at a minimum, the concept of lean PM steel design is one worth investigating; where a lean steel entails that each and every alloying addition is utilized to its maximum potential.
This study evaluates the homogenization behaviour of alloying elements in PM steels during sintering as well as the efficiency of wide-spread industrial practices involving the use of various master alloys and ferroalloys, and investigates the realm of liquid phase sintering to understand and optimize the homogenization behaviour of alloying elements and mechanical properties of PM steels. In the context of this work, multi-component master alloys contain at least three of non-ferrous metals as alloying elements and ferroalloys are master alloys containing iron in addition to typically a maximum of two other non-ferrous alloying additions. Part one of this study discusses a combination of thermodynamic software (DICTRA and Thermo-Calc), incremental sintering experiments and scanning electron microscopy (SEM) - wavelength dispersive spectroscopy (WDS) that were used in order to form a deeper understanding of the homogenization behaviour of alloying elements within PM steel during sintering. Electron microscopy analyses on partially and industrially sintered components provide elemental maps to track the evolution of alloying elements as they relax to homogeneity. Electron microscopy analyses for this portion of the study were conducted on an industryproduced automotive component that was sectioned and sintered industrially as well as experimentally at 1280°C for 30 minutes and 13.4 hours.
DICTRA simulations carried out for this research provide a 1-D insight into the evolution of concentration profiles and phases throughout various sintering times for systems involving Cr, Mn, C and Fe. DICTRA simulation results of alloying sources were studied alongside alloying element profiles obtained by compiling point quantification from wavelength dispersive spectroscopy maps for the sintered automotive component. Computational results provided conservative, semi-quantitative recommendations on optimal alloy addition forms that lead to an improvement in homogenization. Part two of this study involves the approach of fabricating and testing multi-component master alloy additions. As these materials are widely employed in PM and are typically fabricated by solidification, their states are non-equilibrium and therefore have regions containing phases precipitating in the beginning of freezing which have higher melting temperatures than regions with phases forming later on. During heating, it is hypothesized that Scheil’s solidification path backtracks and as a result, a fraction of liquid in the ferroalloy can be estimated at sintering temperature. If the fraction is significant, the utilization of this ferroalloy implies liquid phase sintering. Through a combination of Thermo-Calc and Fortran softwares, multi-component ferroalloys with promising compositions were discovered in Fe-C-Cr-Mn, Fe-C-Cr-Mn-Ni, FeC-Mn-Mo, Fe-C-Mn-Mo-Ni and Fe-C-Cr-Mn-Mo-Ni systems for low temperature liquid phase sintering. Those of the Fe-C-Cr-Mn-Mo, Fe-C-Cr-Mn-Mo-Ni and Fe-Mn-Mo-Ni system were fabricated and tried in practice. Compositional maps and mechanical properties of PM steels made with variations of this specially tailored multi-component master alloys were compared with those for which traditional alloy additions were used. / Thesis / Master of Applied Science (MASc)
|
30 |
Ferric chloride from crude copperasStevens, John January 1939 (has links)
Ferrous sulfate, commercially known as copperas, is a by-product of many industries such as the steel industry where steel is “pickled” in sulfuric acid previous to galvanizing, and in ore refining where sulfuric acid is used to remove undesirable impurities consisting chiefly of iron materials.
One of the chief uses of copperas is as a coagulant in water treatment.
Crude copperas, as produced, does not meet these specifications and must be refined and reworked before it is suitable for use. Consequently, in many instances no attempt is made to make further use of the copperas and it is dumped aside as refuse. It is the purpose of this investigation to use this crude copperas to produce an iron salt suitable for use as a coagulant.
Crude copperas can be used to make a solution of ferric chloride by reacting it with calcium chloride, filtering off the precipitate of calcium sulfate, and oxidizing the ferrous iron to ferric iron with chlorine gas. The calcium content of the ferric chloride solution is low enough so that the hardness of water treated with i it will not be appreciably increased. / M.S.
|
Page generated in 0.0385 seconds