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Metal-oxidizer combustion

STORAGE Keep in a cool, dry, well-ventilated area away from amines, acids, alkalis, oxidizers, metal oxides, combustibles preferable outside or detached storage. [Pg.162]

The complexity of the matter is huge since the oxidation of nAl particles depends on thermodynamical, physical, and chemical features of the reactants involved. In addition to metal-oxidizer combustion, the characteristic size of nAl powders (typically 100 nm or less) deserves further consideration. In the nanometric range, the particle can be composed by few thousands or even few hundreds of atoms. The cohesive energy of atomic clusters is expected to be inversely dependent by the particle radius while surface energy increases and may become non-negligible. Several particle properties such as melting temperature, reactivity, and surface tension may differ from the bulk features [4, 10, 11]. Regarding calorimetric... [Pg.125]

NlTROPROPANE CH3CH(NOi)CH, sec-N it ropropanc Amines, strong acids, alkalies, and oxidizers, metal oxides, combustible materiab S2 Z.6 9... [Pg.227]

Utility systems as sources of waste. The principal sources of utility waste are associated with hot utilities (including cogeneration systems) and cold utilities. Furnaces, steam boilers, gas turbines, and diesel engines all produce waste from products of combustion. The principal problem here is the emission of carbon dioxide, oxides of sulfur and nitrogen, and particulates (metal oxides, unbumt... [Pg.290]

Aluminum-containing propellants deflver less than the calculated impulse because of two-phase flow losses in the nozzle caused by aluminum oxide particles. Combustion of the aluminum must occur in the residence time in the chamber to meet impulse expectations. As the residence time increases, the unbumed metal decreases, and the specific impulse increases. The soHd reaction products also show a velocity lag during nozzle expansion, and may fail to attain thermal equiUbrium with the gas exhaust. An overall efficiency loss of 5 to 8% from theoretical may result from these phenomena. However, these losses are more than offset by the increase in energy produced by metal oxidation (85—87). [Pg.39]

Determined, for the combustion to metal oxides in the presence of oxygen. To convert to cal, divide by 4.184. [Pg.67]

The problems with the combustion reaction occur because the process also produces many other products, most of which are termed air pollutants. These can be carbon monoxide, carbon dioxide, oxides of sulfur, oxides of nitrogen, smoke, fly ash, metals, metal oxides, metal salts, aldehydes, ketones, acids, polynuclear hydrocarbons, and many others. Only in the past few decades have combustion engineers become concerned about... [Pg.78]

The advantage is an oxidation temperature of 500°F compared to non-catalytic combustion of 1500°F. The active ingredients used were platinum, as well as the base metal oxides of cobalt, nickel, manganese, chromium, and iron. The support material included nickel-chromium ribbons, ceramics rods, beads, and pellets (13-17). [Pg.62]

Seven chemical reactions were identified from the chemistry syllabus. These chemical reactions were selected because they were frequently encountered during the 2-year chemistiy course and based on their importance in understanding concepts associated with three topics, namely, acids, bases and salts, metal reactivity series and inorganic chemistry qualitative analysis. The seven types of chemical reactions were combustion of reactive metals in air, chemical reactions between dilute acids and reactive metals, neutralisation reactions between strong acids and strong alkalis, neutralisation reactions between dilute acids and metal oxides, chemical reactions between dilute acids and metal carbonates, ionic precipitation reactions and metal ion displacement reactions. Although two of the chemical reactions involved oxidation and reduction, it was decided not to include the concept of redox in this study as students had only recently been introduced to ion-electron... [Pg.155]

Transition metal oxides represent a prominent class of partial oxidation catalysts [1-3]. Nevertheless, materials belonging to this class are also active in catalytic combustion. Total oxidation processes for environmental protection are mostly carried out industriaUy on the much more expensive noble metal-based catalysts [4]. Total oxidation is directly related to partial oxidation, athough opposes to it. Thus, investigations on the mechanism of catalytic combustion by transition metal oxides can be useful both to avoid it in partial oxidation and to develop new cheaper materials for catalytic combustion processes. However, although some aspects of the selective oxidation mechanisms appear to be rather established, like the involvement of lattice catalyst oxygen (nucleophilic oxygen) in Mars-van Krevelen type redox cycles [5], others are still uncompletely clarified. Even less is known on the mechanism of total oxidation over transition metal oxides [1-4,6]. [Pg.483]

In the following scheme, an oxidation pathway for propane and propene is proposed. This mechanism, that could be generalized to different hansition metal oxide catalysts, implies that propene oxidation can follow the allylic oxidation way, or alternatively, the oxidation way at C2, through acetone. The latter easily gives rise to combustion, because it can give rise to enolization and C-C bond oxidative breaking. This is believed to be the main combustion way for propene over some catalysts, while for other catalysts acrolein overoxidation could... [Pg.488]

Underneath this layer of superoxide a layer of oxide KgO is formed. The interaction between potassium and its superoxide is violent and causes the metal to combust the intermediate layer acts as a protection. Contact between both compounds happens when the metal is cut. This slow oxidation is avoided by keeping potassium under anhydrous xylene. It is possible that many dangerous reactions may be in fact due to the exceptional reactivity of the superoxide. [Pg.193]

CLC consists of two fluidised bed reactors, namely reducer and oxidiser. In the reducer reactor, fuel is fed along with the metal oxide containing oxygen, which is transferred from the metal oxide to the reactor as the combustion occurs (Figure 7). A flue gas containing over 99%v/v of C02 can be obtained by a simply condensation stage because of the fact that the exhaust gas at the reducer outlet is primarily formed by C02 and water vapour. This stream is then sent to further compression and permanent storage. [Pg.88]

In a review of the course and mechanism of the catalytic decomposition of ammonium perchlorate, the considerable effects of metal oxides in reducing the explosion temperature of the salt are described [1], Solymosi s previous work had shown reductions from 440° to about 270° by dichromium trioxide, to 260° by 10 mol% of cadmium oxide and to 200°C by 0.2% of zinc oxide. The effect of various concentrations of copper chromite , copper oxide, iron oxide and potassium permanganate on the catalysed combustion of the propellant salt was studied [2], Similar studies on the effects of compounds of 11 metals and potassium dichromate in particular, have been reported [3], Presence of calcium carbonate or calcium oxide has a stabilising effect on the salt, either alone or in admixture with polystyrene [4],... [Pg.1367]

S02 and NOx in flue gas from coal combustion contribute to smog and acid rain. Methods to remove these pollutants include alkaline wet scrubber systems that fix S02 to solid CaS04, and selective catalytic reduction by metal/metal oxide systems of NO/NOz to N2 and steam in the presence of ammonia. Particulate active carbons have also been used in flue gas decontamination, especially as they avoid costly scrubber processes and can operate at lower temperatures. The potential of active carbon fibers in this application has been explored by a... [Pg.123]

FIS Metal Oxide Lambda Sensor LS-01 for COMBUSTION CONTROLS. Technical In-... [Pg.51]


See other pages where Metal-oxidizer combustion is mentioned: [Pg.231]    [Pg.4980]    [Pg.467]    [Pg.231]    [Pg.4980]    [Pg.467]    [Pg.259]    [Pg.39]    [Pg.494]    [Pg.42]    [Pg.43]    [Pg.351]    [Pg.3]    [Pg.179]    [Pg.194]    [Pg.526]    [Pg.508]    [Pg.512]    [Pg.87]    [Pg.495]    [Pg.265]    [Pg.159]    [Pg.444]    [Pg.446]    [Pg.194]    [Pg.360]    [Pg.720]    [Pg.50]    [Pg.563]    [Pg.643]    [Pg.88]    [Pg.1653]    [Pg.1853]    [Pg.500]    [Pg.512]    [Pg.153]    [Pg.161]   
See also in sourсe #XX -- [ Pg.125 ]




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