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Bitumin

Fillers are also used in the preparation of paper to improve the properties of the material and are added to bituminous materials such as plastics and road surfacing materials. [Pg.175]

Distillation of cutbacks and fluxed bituminous products NF T 66-003 ASTM D 402 Distillation... [Pg.447]

Ductility of bituminous materials NF T 66-006 ASTM D 113 Test-sample elongation at the point of rupture... [Pg.447]

Relative density (specific gravity) of bituminous materials NF T 66-007 ASTM D 70 Pycnometer... [Pg.449]

Solubility (bituminous products) NFT 66-012 ASTM D 4 Dissolving, filtration, weighing... [Pg.450]

Apparently a negative AP with Q < 90° can be found for particular pore geometries [53]. A different type of water repellency is desired to prevent the deterioration of blacktop roads consisting of crushed rock coated with bituminous materials. Here the problem is that water tends to spread into the stone-oil interface, detaching the aggregate from its binder [54]. No entirely satisfactory solution has been found, although various detergent-type additives have been found to help. Much more study of the problem is needed. [Pg.471]

Coals (the plural is deliberately used because coal has no defined, uniform nature or structure) are fossil sources with low hydrogen content. The structure of coals means only the structural models depicting major bonding types and components relating changes with coal rank. Coal is classified, or ranked, as lignite, subbituminous, bituminous, and anthracite. This is also the order of increased aromaticity and decreased volatile matter. The H C ratio of bituminous coal is about 0.8, whereas anthracite has H C ratios as low as 0.2. [Pg.131]

Location Anthracite and bituminous coal Lignite Total... [Pg.422]

The chemical characteristics of biomass vary over a broad range because of the many different types of species. Table 8 compares the typical analyses and energy contents of land- and water-based biomass, ie, wood, grass, kelp, and water hyacinth, and waste biomass, ie, manure, urban refuse, and primary sewage sludge, with those of cellulose, peat, and bituminous coal. Pure cellulose, a representative primary photosynthetic product, has a carbon content of... [Pg.13]

Analysis Pure ceUulos e Pine wood Kentuck y bluegrass Giant brown kelp Feedlo t manur e Urban refuse Primary sewage sludge Reed sedge peat Illinois bituminous coal... [Pg.14]

Physical Properties. Physical properties of waste as fuels are defined in accordance with the specific materials under consideration. The greatest degree of definition exists for wood and related biofuels. The least degree of definition exists for MSW, related RDF products, and the broad array of ha2ardous wastes. Table 3 compares the physical property data of some representative combustible wastes with the traditional fossil fuel bituminous coal. The soHd organic wastes typically have specific gravities or bulk densities much lower than those associated with coal and lignite. [Pg.53]

Typically, 40—50% of the carbon atoms ia lignite are ia aromatic stmctures while 60—70% of the carbon atoms ia Illinois bituminous coal are ia aromatic stmctures (7,8). By all of these measures, waste fuels are significantly more reactive than coal, peat, and other combustible soHds. [Pg.54]

Properties. Pilot-unit data indicate the EDS process may accommodate a wide variety of coal types. Overall process yields from bituminous, subbituminous, and lignite coals, which include Hquids from both Hquefaction and Flexicoking, are shown in Figure 14. The Hquids produced have higher nitrogen contents than are found in similar petroleum fractions. Sulfur contents reflect the sulfur levels of the starting coals ca 4.0 wt % sulfur in the dry bituminous coal 0.5 wt % in the subbituminous and 1.2 wt % sulfur in the dry lignite. [Pg.91]

Properties. A high volatile western Kentucky bituminous coal, the tar yield of which by Fischer assay was ca 16%, gave a tar yield of ca 26% at a pyrolysis temperature of 537°C (146—148). Tar yield peaked at ca 35% at 577°C and dropped off to 22% at 617°C. The char heating value is essentially equal to that of the starting coal, and the tar has a lower hydrogen content than other pyrolysis tars. The product char is not suitable for direct combustion because of its 2.6% sulfur content. [Pg.94]

See other pages where Bitumin is mentioned: [Pg.61]    [Pg.61]    [Pg.61]    [Pg.103]    [Pg.119]    [Pg.239]    [Pg.166]    [Pg.127]    [Pg.117]    [Pg.117]    [Pg.117]    [Pg.479]    [Pg.939]    [Pg.53]    [Pg.64]    [Pg.68]    [Pg.72]    [Pg.89]    [Pg.89]    [Pg.91]    [Pg.92]    [Pg.92]    [Pg.92]    [Pg.93]    [Pg.93]    [Pg.93]    [Pg.93]    [Pg.93]    [Pg.98]    [Pg.142]    [Pg.142]    [Pg.142]    [Pg.142]    [Pg.143]    [Pg.143]    [Pg.143]    [Pg.143]   
See also in sourсe #XX -- [ Pg.864 ]

See also in sourсe #XX -- [ Pg.70 ]



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ASPHALT - BITUMINOUS MATERIALS

Adhesivity of bituminous emulsions by water immersion test

Appalachian bituminous coal basin

Aromaticity volatile bituminous coals

Behaviour of bituminous mixture under creep (static) and cyclic compressive loading

Bituminous

Bituminous

Bituminous Coal Annual

Bituminous Coal Institute

Bituminous Coal Operators Association

Bituminous Coal Research

Bituminous binder

Bituminous carbon

Bituminous cements

Bituminous cements testing

Bituminous coal

Bituminous coal Pittsburgh

Bituminous coal char gasification

Bituminous coal dust

Bituminous coal heteroatoms

Bituminous coal high-volatile

Bituminous coal high-volatile, distribution

Bituminous coal macerals, distribution

Bituminous coal middle oil

Bituminous coal mining

Bituminous coal organic acids

Bituminous coal phenanthrene extraction

Bituminous coal process flow diagram

Bituminous coal samples, pyritic

Bituminous coal tar

Bituminous coal with density

Bituminous coal, Pittsburgh Seam

Bituminous coal, devolatilization

Bituminous coal, pyrolysis product

Bituminous coal, rapid pyrolysis

Bituminous coals analyses

Bituminous coals elemental analysis

Bituminous coals lignites

Bituminous coals mineralogy

Bituminous coals minerals

Bituminous coals products

Bituminous coals sulfur contents

Bituminous concrete

Bituminous emulsion

Bituminous froth

Bituminous geomembrane

Bituminous limestone

Bituminous macadam

Bituminous materials

Bituminous materials roofing

Bituminous matter

Bituminous membranes

Bituminous paints

Bituminous paving composition

Bituminous plastics

Bituminous rock

Bituminous sand

Bituminous slurry

Bituminous substances

Calcite-rich bituminous coal

Coal, bituminous, trace elements

Coatings bituminous

Cut-back and fluxed bituminous binders

Delta ring and ball test of filler for bituminous mixtures

Emissions combustion, bituminous coal

High sulfur bituminous coal

High volatile A bituminous coal

High-rank bituminous coal

Inspection and testing of finished bituminous mixture

Liquefaction Monterey bituminous

Low-volatile bituminous coal

Low-volatility bituminous coal

Methods of sampling bituminous binders

Monterey coal , liquefaction bituminous

Organic bituminous coal

Oxidized bituminous coal

Paint types bituminous

Polymer-modified bituminous roofing

Polymer-modified bituminous roofing membranes

Rapid bituminous coals

Roofing felts bituminous

Rutting of Bituminous Concrete

Sub-bituminous

Sub-bituminous coal

Sulfur bituminous coal

Sulfur bituminous coal samples

Synthetic fuels from bituminous coal

Target composition of the bituminous mixture

Tertiary bituminous coals

Test Method for Penetration of Bituminous Materials

Tetralin with bituminous coal, reaction

Thickness determination of bituminous layers

Type and quantity of bituminous binder

United bituminous coals from

Volatile bituminous coals, variation

Volatile yields from bituminous coal

Volumetric properties of compacted bituminous mixture

Water susceptibility of fillers for bituminous mixtures

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