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Dome, doming

The foams, marketed by Rohm as Rohacell, are stable at room temperature to hydrocarbons, ketones, chlorinated solvents and 10% sulphuric acid. They may be used under load at temperature up to 160°C. Uses quoted for these materials include bus engine covers, aircraft landing gear doors, radar domes, domes, ski cores and tennis racket cores. Their potential is in applications demanding a level of heat deformation resistance, solvent resistance and stiffness not exhibited by more well-known cellular polymers such as expanded polystyrene and the polyurethane foams. [Pg.421]

The discovery of perfect geodesic dome closed structures of carbon, such as C o has led to numerous studies of so-called Buckminster fullerene. Dislocations are important features of the structures of nested fullerenes also called onion skin, multilayered or Russian doll fullerenes. A recent theoretical study [118] shows that these defects serve to relieve large inherent strains in thick-walled nested fullerenes such that they can show faceted shapes. [Pg.278]

Medeiros G ef al 1998 Shape transition of germanium nanocrystals on a silicon (001) surface from pyramids to domes Science 279 353... [Pg.2923]

In America, the sulphur deposits (mostly in Louisiana and Texas) are dome-shaped layers about 30 cm thick, between limestone above and anhydrite below. From these, the sulphur is extracted by the Frasch process. A metal tube, about 15 cm diameter and containing two concentric inner tubes (Figure 10.1) is sunk into the top of the deposit. Water, superheated to 450 K, is forced... [Pg.261]

Sulfur is commercially recovered from wells sunk into the salt domes along the Gulf Goast of the U.S. Using the Frasch process heated water is forced into the wells to melt the sulfur, which is then brought to the surface. [Pg.38]

Buckminsterfullerene (Chapter 11 essay Carbon Clusters Fullerenes and Nanotubes ) Name given to the Cgo cluster with structure resembling the geodesic domes of R Buck minster Fuller see front cover... [Pg.1278]

Note These equations are from Doming, S. N. Morgan, S. L. Experimental Design A Chemometric Approach. Elsevier Amsterdam, 1987, and pseudo-three-dimensional plots of the response surfaces can be found in their figures 11.4, 11.5, and 11.14. The response surface for problem (a) also is shown in Color Plate 13. [Pg.700]

Steel. The steel container s most usual form is cylindrical with a concave (or flat) bottom and a convex top dome with a circular opening finished to receive a valve with a standard 2.54-cm opening. The three pieces (body, bottom, and top) are produced separately and joined by high speed manufacturing. The size of the container is described by its diameter and height to top seam, in that order. Hence a 202 x 509 container is 54.0 mm (2 /jg in.) in diameter by 141.3 mm (5 /jg in.) high. Tables of available sizes and overflow volumes and suggested fill levels can be readily obtained from manufacturers. [Pg.349]

Jets for continuous filament textile yam are typically 1 cm diameter gold—platinum ahoy stmctures with 20—500 holes of 50—200 p.m diameter. Tire yam jets are also 1 cm in diameter but typicahy use 1000—2000 holes to give the required balance of filament and yam denier. Staple fiber jets can have as many as 70,000 holes and can be made from a single dome of ahoy or from clusters of the smaller textile or tire yam jets. The precious metal ahoy is one of the few materials that can resist the harsh chemical environment of a rayon machine and yet be ductile enough to be perforated with precision. Glass jets have been used for filament production, and tantalum metal is a low cost but less durable alternative to gold—platinum. [Pg.348]

Electrical Properties. CeUular polymers have two important electrical appHcations (22). One takes advantage of the combination of inherent toughness and moisture resistance of polymers along with the decreased dielectric constant and dissipation factor of the foamed state to use ceUular polymers as electrical-wire insulation (97). The other combines the low dissipation factor and the rigidity of plastic foams in the constmction of radar domes. Polyurethane foams have been used as high voltage electrical insulation (213). [Pg.415]

The roof, in the form of a dome, is either comprised of refractory brick held in place by a water-cooled steel roof ring, or it may be composed of water-cooled panels. Sometimes water-cooled rings or glands are placed on the roof around the electrodes to maintain the refractory. On high power furnaces refractory is used around the electrodes to minimize the possibiUty of electrical short circuits. [Pg.121]

Unusual behavior has also been observed in soHd mixtures of He and He. In principle, all soHd mixtures should separate as absolute 2ero is approached, but because of kinetic limitations, this equiHbrium condition is almost never observed. However, because of high diffusivity resulting from the large 2ero-point motion in soHd helium, this sort of separation takes place in a matter of hours in soHd mixtures of He and He (53,61). The two-phase region for the soHd mixture is outlined by the dashed curve in Figure 4. The two-phase dome is shallow, and its temperature maximum is 0.38 K. [Pg.9]

Most architectural fabrics are usually flexible composites comprised of glass fibers coated with fluorocarbons to resist wind, mechanical forces, and outdoor environmental degradation. The airport terminal in Saudi Arabia, and the roofs for the Hubert Humphrey Dome in Minneapolis and the Tokyo Dome Stadium are a few examples of the successful use of architectural fabrics. [Pg.72]

Hydroboration of a,C0-dienes with monoalkylboranes gives reactive organoboron polymers which can be transformed into polymeric alcohols or polyketones by carbonylation, cyanidation, or the DOME reaction followed by oxidation (446—448). [Pg.321]

The first of these reactions takes place at temperatures of about 150°C, the second reaction proceeds at about 550—660°C. Typical furnaces used to carry out the reaction include cast-iron retorts the Mannheim mechanical furnace, which consists of an enclosed stationary circular muffle having a concave bottom pan and a domed cover and the Laury furnace, which employs a horizontal two-chambered rotating cylinder for the reaction vessel. The most recent design is the Cannon fluid-bed reactor in which the sulfuric acid vapor is injected with the combustion gases into a fluidized bed of salts. The Mannaheim furnace has also been used with potassium chloride as the feed. [Pg.445]

Methylene iodide [75-11-6], CH2I2, also known as diio dome thane, mol wt 267.87, 94.76% I, mp 6.0°C, and bp 181°C, is a very heavy colorless Hquid. It has a density of 3.325 g/mL at 20°C and a refractive index of 1.7538 at 4°C. It darkens in contact with air, moisture, and light. Its solubiHty in water is 1.42 g/100 g H2O at 20°C it is soluble in alcohol, chloroform, ben2ene, and ether. Methylene iodide is prepared by reaction of sodium arsenite and iodoform with sodium hydroxide reaction of iodine, sodium ethoxide, and hydroiodic acid on iodoform the oxidation of iodoacetic acid with potassium persulfate and by reaction of potassium iodide and methylene chloride (124,125). Diiodoform is used for determining the density and refractive index of minerals. It is also used as a starting material in the manufacture of x-ray contrast media and other synthetic pharmaceuticals (qv). [Pg.366]

Acidic contaminants are poisonous to the alcoholysis catalysts and must be avoided. If the oil has a high acid number, or there are high acidity residues left in the reactor from the previous batch, such as sublimed phthaUc anhydride condensed under the dome of the reactor, the reaction can be severely retarded. A longer batch time or additional amount of catalyst is then required. Both are undesirable. [Pg.38]

The demand for gas is highly seasonal. Thus pipeline companies economi2e by si2ing production faciUties to accommodate less than the system s maximum wintertime demand. Underground storage faciUties are used to meet seasonal and daily demand peaks. In North America, gas is stored in three main types of underground formations depleted oil or gas fields, aquifers that originally contained water, and caverns formed by salt domes or mines. [Pg.17]

Harvested and defivered whole, the trees are dried ia an air-supported fiber glass dome stmcture over a 30-d period by usiag waste heat from the combustioa process ia the adjaceat plant (Pig. 5). Trees leave the dome on the conveyor and, at the boiler wall, batches ate cut iato sectioas to fit the boiler. These sectioas are about 8.5 mloag for the 100-MW facility studied by EPRI and the Mianesota Power Light Company. [Pg.107]


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See also in sourсe #XX -- [ Pg.142 ]




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Bottom dome

Concave domes

Conoidal domes surfaces

Cort-Dome

Cort-Dome - Hydrocortisone

Costa Rica Dome

DTIC-Dome

Design of domed ends

Diaphragm doming

Die doming

Dome Forming

Dome Home

Dome Laboratories

Dome Matrix

Dome Matrix® technology

Dome Petroleum

Dome Prestressing Description of Tendon Arrangement

Dome Vertical Components

Dome formation

Dome nuts

Dome placement

Dome structures

Dome tendon

Dome type reactor

Dome, condenser

Domed heads

Domed heads (pressure vessels

Domed salt

Domes

Domes

Doming

Double Dome

Elliptical Dome-Shaped Surfaces of the Vessel

Elliptical dome

Endogenous domes

Exogenous domes

Failure domed

Filament-winding dome

Fixed dome digesters

Free-standing domes

Fuller, Buckminster, geodesic domes

Fuller’s geodesic dome

Geodesic dome

Glass dome operation

Hemispherical domes

Kettleman North Dome

Liquid-vapor dome

Metal domes

Metal domes switch contacts

Methoxa-dome

Millennium Dome

Miscibility dome

Musca domes tica

Porphyrins doming

Radar dome

Rhyolite flow-dome

Salt domes

Salt from domes

Salt-dome calcite

Secondary dome

Storage salt dome

Top dome

Torispherical Shell Surfaces of the Reactor Vessel Top Dome

Upper dome

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