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1.
More than 3800 coal thickness measurements, proximate analyses from 97 localities, and stratigraphic and sedimentological analyses from more than 300 outcrops and cores were used in conjunction with previously reported palynological and petrographic studies to map individual benches of the coal and document bench-scale variability in the Fire Clay (Hazard No. 4) coal bed across a 1860 km2 area of the Eastern Kentucky Coal Field. The bench architecture of the Fire Clay coal bed consists of uncommon leader benches, a persistent but variable lower bench, a widespread, and generally thick upper bench, and local, variable rider benches. Rheotrophic conditions are inferred for the leader benches and lower bench based on sedimentological associations, mixed palynomorph assemblages, locally common cannel coal layers, and generally high ash yields. The lower bench consistently exhibits vertical variability in petrography and palynology that reflects changing trophic conditions as topographic depressions infilled. Infilling also led to unconfined flooding and ultimately the drowning of the lower bench mire. The drowned mire was covered by an air-fall volcanic-ash deposit, which produced the characteristic flint clay parting. The extent and uniform thickness of the parting suggests that the ash layer was deposited in water on a relatively flat surface without a thick canopy or extensive standing vegetation across most of the study area. Ash deposits led to regional ponding and establishment of a second planar mire. Because the topography had become a broadly uniform, nutrient-rich surface, upper-bench peats became widespread with large areas of the mire distant to clastic sources. Vertical sections of thick (>70 cm), low-ash yield, upper coal bench show a common palynomorph change from arborescent lycopod dominance upward to fern and densospore-producing, small lycopod dominance, inferred as a shift from planar to ombrotrophic mire phases. Domed mires appear to have been surrounded by wide areas of planar mires, where the coal was thinner (<70 cm), higher in ash yield, and dominated by arborescent lycopods. Rectangular thickness trends suggest that syndepositional faulting influenced peat accumulation, and possibly the position of the domed mire phase. Faulting also influenced post-depositional clastic environments of deposition, resulting in sandstone channels with angular changes in orientation. Channnels and lateral facies were locally draped by high-ash-yield rider coal benches, which sometimes merged with the upper coal bench. These arborescent-lycopod dominant rider coal benches were profoundly controlled by paleotopography, much like the leader coal benches. Each of the benches of coal documented here represent distinctly different mires that came together to form the Fire Clay coal bed, rather than a single mire periodically split by clastic influx. This is significant as each bench of the coal has its own characteristics, which contribute to the total coal characteristics. The large data set allows interpretation of both vertical and lateral limits to postulated domed phases in the upper coal bench, and to the delineation of subtle tectonic structures that allow for meaningful thickness projections beyond the limits of present mining. 相似文献
2.
J. H. Calder M. R. Gibling C. F. Eble A. C. Scott D. J. MacNeil 《International Journal of Coal Geology》1996,31(1-4)
Strata of Westphalian D age on the western coast of the Sydney Basin expose a fossil forest of approximately 30 lepidodendrid trees within one of several clastic splits of the Harbour Seam. A multidisciplinary approach was employed to interpret the origins of the coat bed, the depositional history of the site and the response of the fossil forest to changing edaphic conditions. The megaspore and miospore records indicate that the mire vegetation was dominated by arboreous lycopsids, especially Paralycopodites, with subdominant tree ferns. Petrographic, palynological and geochemical evidence suggest that the Harbour coal bed at Table Head originated as a rheotrophic (cf. planar) mire (eutric histosol). The mire forest is interpreted to have been engulfed by prograding distributary-channel sediments; sparse protist assemblages are suggestive of a freshwater delta-plain lake environment occasionally in contact with brackish waters. Lepidodendrids persisted as site colonizers of clastic substrates even after burial of the rheotrophic peatland and influenced the morphology of deposited sediment, but apparently were unable to colonize distributary channels. Equivocal taxonomic data (compression fossils) show the fossil forest to have been composed of both monocarpic (Lepidodendron) and polycarpic (Diaphorodendron, Paralycopodites, ?Sigillaria) lycopsids, genera recorded in the palynology of the uppermost ply of the underlying coal bed. Comparatively rare within the clastic beds of the fossil forest, however, is the stem compression of Paralycopodites, whose dispersed megapores and miospores dominate the underlying coal bed. Tree diameter data recorded equivalent to breast height indicate a forest of mixed age. These data would appear to suggest that some lepidodendrids employing a polycarpic reproductive strategy were better able to cross the ecological barrier imposed between peat and clastic substrates. Foliar compressions indicate that an understory or stand of Psaronius type tree ferns co-existed with the lepidodendrids on clastic substrates, which developed as incipient gleysol soils. The entombment of the forest can be ascribed to its distributary coastal setting, local subsidence and a seasonal climate that fostered wildfire and increased sedimentation. 相似文献
3.
The Springfield (Western Kentucky No. 9) coal of the Carbondale Formation (Middle Pennsylvanian) in the Western Kentucky Coal Field of the Illinois Basin was sampled in eleven mines from one to three channels of three equal benches. The rank of the coal is high-volatile C bituminous in the Moorman Syncline and in the Henderson Basin and high-volatile B bituminous in the Webster Syncline. The percentage of total vitrinite macerals and of total vitrinite plus liptinite was found to decrease significantly from the bottom bench through to the top bench. In a comparison of the sources of variation within the set of maceral data it was found that the only significant variation in the vitrinite and vitrinite plus liptinite percentages was between the benches. Both the rank of the coal and the maceral percentages are varying in a predictable manner. 相似文献
4.
The Herrin (Western Kentucky No. 11) coal bed in the Dixon 7 1/2 min quadrangle, Webster County, Kentucky, displays another manifestation of the thinning margin of the coal bed. Previous studies in adjacent Hopkins County have demonstrated that the coal is brecciated as the margin is approached. The brecciated coal is not always thin; 1.5 m of brecciated, inertinite-rich coal was previously described to the southeast of the present study area. In general, the brecciated coals are considerably thinner than the 1.5–2-m-thick, “normal” Herrin coal. Both cores studied are thin (22.6 and 33 cm) and display petrographic characteristics different from thicker Herrin coals. The cores described in the present study show some signs of brecciation; in certain cases, the fragmented macerals are cemented by exsudatinite. Multiple generations of pyrite mineralization were noted in one core, with total sulfur exceeding 13% in the upper 8.48 cm lithotype.Overall, the cores investigated in this study, along with examples from previous studies, illustrate the progression of the Herrin coal from its absence, either through nondeposition or erosion, through thin, brecciated coals, to mineable coals. No other economic coal in western Kentucky shows as many examples of the depositional edge as does the Herrin. All of the examples studied are from cores, emphasizing the need to study more than just the thick, mineable coals if the total extent of the coal body is to be understood. 相似文献
5.
Two thermal parameters, initial volatilization temperature (IVT) and average volatilization rate (AVR), have been determined by thermogravimetric analysis in argon for 38 coal samples ranging in rank from lignite to low-volatile bituminous. Both IVT and AVR are correlated with percent volatile matter and vitrinite reflectance.The IVT values increase gradually from about 250 to 445°C with increasing rank; however, a change in slope is observed in the region of high-volatile bituminous coals (from about 340°C to about 380°C) when IVT's are plotted against percent volatile matter or percent fixed carbon. The changes in slope near 340°C and near 380°C occur at “coalification jumps” recognized on the basis of changes in the optical and chemical character of the macerals. In general, AVR values decrease gradually with increasing rank for the lignite and sub-bituminous coals and for the medium- and low-volatile bituminous coals; however, a sharp increase in AVR occurs in high-volatile bituminous coals. The change in slope of the IVT curves and sharp increase in the AVR values for high-volatile bituminous coals reflect the development of new, higher vapor pressure organic compounds produced during this stage of the coalification process.A plot of AVR vs IVT reveals three regions which correspond to: (1) lignite and sub-bituminous coals; (2) high-volatile bituminous coals; and (3) medium- to low-volatile bituminous coals. 相似文献
6.
James C. Hower David A. Williams Cortland F. Eble Tanaporn Sakulpitakphon David P. Moecher 《International Journal of Coal Geology》2001,47(3-4)
Coals from the D-2 and D-3 boreholes in the Grove Center 7 1/2 min quadrangle, Union County, KY, have been found to be highly brecciated and mineralized. The mineralization is dominated by a carbonate assemblage with minor sulfides and sulfates. Included among the secondary minerals is the lead selenide, clausthalite. Overall, the emplacement of secondary vein minerals was responsible for raising the rank of the coals from the 0.6–0.7% Rmax range found in the area to as high as 0.95–0.99% Rmax.A 1.3-m-thick coal found in one of the boreholes is unique among known Western Kentucky coals in having less than 50% vitrinite. Semifusinite and fusinite dominate the maceral assemblages. The coal is also low in sulfur coal, which is unusual for the Illinois Basin. It has an ash yield of less than 10%; much of it dominated by pervasive carbonate veining. The age of the thick coal in core D-2 is similar to that of the Elm Lick coal bed, found elsewhere in the Western Kentucky coalfield. The coals in D-3 are younger, having Stephanian palynomorph assemblages. 相似文献
7.
Summary A two dimensional finite element procedure is applied to simulate a coal mining excavation sequence. A procedure with linear solution steps is developed and applied to an idealized mountain cross-section with exceptionally thick coal seams and large dip angle. The results provide information on pillar pressure, floor and roof stability, displacement characteristics and surface subsidence.The results presented here were obtained in the course of research sponsored by the Department of Energy, Mines and Resources, Grant No. 69-2570. 相似文献
8.
煤层风氧化带宽度的确定方法 总被引:1,自引:0,他引:1
在煤炭资源储量估算中,煤层风氧化带垂深都是根据煤质化验指标来确定,对在煤层底板等高线上如何确定煤层风氧化带宽度没有明确的规定,为此,依据实际工作中遇到的三种地质情况:地表基本平坦:地表有倾角且倾向与煤层倾向相同;地表有倾角且倾向与煤层倾向相反,分别用制图法、计算法确定其煤层风氧化带的宽度。 相似文献
9.
David H. Zeuch 《Tectonophysics》1982,83(3-4)
Twiss (1976) has suggested that the “ductile faulting” events observed by Post (1973) during high temperature creep of dunite are due to a transition from creep by dislocation movement to a diffusion accommodated, grain-boundary sliding mechanism following a reduction in grain size by dynamic recrystallization. Similarly, Goetze (1978) has explained both ductile faulting and water weakening of dunite by transition to a “nonlinear Coble” creep mechanism. However, the fundamental assumption made by Twiss (1976) that the stress exponent, n, reduces to unity during ductile faulting events is questionable. If the stress exponent remains high, (n≥3), then a diffusion-accomodated grain-boundary sliding mechanism is excluded. “Nonlinear Coble” creep would remain a viable alternative; however, this model fails to adequately explain the water weakening phenomenon, and the available data do not constrain us to this model. Assuming that the water-weakening phenomenon can be explained by other models (e.g., Blacic, 1972), it will be shown (by analogy with the behavior of metals) that a third model, also consistent with the available data, also qualitatively explains the observations associated with ductile faulting without appeal to a transition in creep mechanisms. The model is similar to one for metals undergoing deformation by dislocation movement and recovery by dynamic recrystallization, which commonly exhibit behavior virtually identical to that observed in dunite during ductile faulting events without transition to grain-size-sensitive creep mechanisms. 相似文献
10.
通过对沁水盆地安泽区块煤层气地质条件和储层条件的深入分析,探讨了该区煤层气的富集规律及主要影响因素。研究发现,煤的岩石学特征、构造、顶底板岩性是影响煤层气富集的主要因素。总体上,安泽区块煤储层含气量受煤阶影响,表现为:煤的变质程度越高,吸附能力整体增强,含气量增大。局部区域,煤层气含量受煤层埋深、断层、褶皱及煤层顶底板岩性等综合因素的影响。在构造平缓带,煤层气含量随埋深增大而增大;在构造活动带,正断层上升盘含气量明显低于下降盘含气量,断层对煤层气的逸散作用明显。此外,泥岩顶底板封盖较砂岩顶底板封盖能力强。 相似文献
11.
Yunxing Cao Gareth D. Mitchell Alan Davis Daming Wang 《International Journal of Coal Geology》2000,43(1-4)
Tectonic displacement of coal seams in China has resulted in faulting parallel to coal bedding. Displacement along these faults caused significant comminution of the coal on the footwall contributing to various mining problems, the worst of which is catastrophic failure, or “outbursting” of the working face during mining. The granular texture and mostly unconsolidated nature of the coal suggests that faulting occurred relatively late in the coalification sequence, at a time of maximum tectonic stress. Coal samples taken on either side of the fault plane (normal and deformed coal layers) were obtained in an effort to establish what influence these tectonic stresses might have had on coal properties as well as what they might reveal about the influence of tectonic pressure on organic maturity. Sample sets were collected within coal beds from undisturbed and adjacent deformed layers, including 21 bituminous samples from the Pingdingshan coal field and nine anthracite samples from the Jiaozuo coal field, the Tieshenggou coal mine of the Yuxi coal field in Henan province, the Beijing Xishan coal field, the Baijiao mine of the Furong coal field in Sichuang province and the Baisha coal field in Hunan province, China. Results from vitrinite reflectance, proximate and ultimate analyses show some differences in reflectance, hydrogen content and nitrogen content of anthracite coal. No significant difference was found between volatile matter yields of normal and deformed coal specimens. GC measurements of the saturated hydrocarbon fraction of chloroform extracts from bituminous coals showed that lower molecular weight carbon fragments were concentrated in the deformed samples. Therefore, although changes in the gross chemical properties of the deformed coal were insignificant, some modification of the chemical structure is seen to have occurred as a result of exposure to tectonic pressure. 相似文献
12.
法国蒙索盆地的断裂活动与泥炭(煤)堆积的关系 总被引:2,自引:0,他引:2
通过对法国斯蒂芬期(C3)的蒙索煤盆地巴哈露天矿1号厚煤层的沉积构成及其同沉积断裂活动对其堆积的控制作用分析,建立了内陆、山间断陷盆地物源近、构造活动强烈、水动力条件变化大、快速充填的沉积─构造背景下的断块成煤模式。早期构造活动性质、方式的改变、沉积充填碎屑岩体类型的变化与成煤期区域构造背景的变化息息相关。 相似文献
13.
Paradise (and Herrin) lost: Marginal depositional settings of the Herrin and Paradise coals, Western Kentucky coalfield 总被引:1,自引:1,他引:0
J.M.K. O'Keefe M.G. Shultz S.M. Rimmer J.C. Hower J.T. Popp 《International Journal of Coal Geology》2008,75(3):144-156
This is the fourth installment in a series of papers on the Asturian (Westphalian D) disrupted mire margins, termed the “ragged edge” in previous papers, and limestone distributions in the Herrin–Baker coal interval in the Western Kentucky extension of the Illinois Basin. New data, indicating in-situ peat development and marine influence, collected from the first in-mine exposure of this interval are presented. Borehole data from the region are examined in the context of “ragged edge” exposures and a carbonate platform depositional model for this portion of the Illinois Basin is presented. This shows that deposition of the sequence was influenced both by the underlying sediments and by a marine transgression. The former influence is seen in variations in coal and limestone thickness over sandstone-filled channels versus over shale bayfill deposits. The latter is marked by the progressive upwards loss of coal benches (i.e., the bottom bench of both coals is the most extensive and the Herrin coal is more extensive than the overlying Paradise coal) and by marine partings in both coals. Further, the brecciated margins seen in both coal seams are similar to brecciated peats encountered along the Everglades margins of Southwest Florida. Overall coal distributions are similar to both those along the Everglades margins and those along a transect from the Belize coast to Ambergis Caye. 相似文献
14.
用倾角变异系数预测芙蓉井田构造发育程度 总被引:1,自引:0,他引:1
根据计算所得煤层底板倾角变异系数R值,将未采区划分为4种构造复杂程度类别,从而找出未采区不同地段断裂构造的差异性,还可根据R值等值线的方向判定未采区主要断裂构造的走向。 相似文献
15.
宁夏香山含煤区掩盖面积大,勘查程度低,空白区多。通过对已有地质资料分析,线驮石煤矿区边界断层为倾向北东的正断层,在东部土坡组露头附近有一倾向南西的正断层,两断层形成地堑使区内的含煤地层得以保存。根据矿区边界断层以西勘查资料推测,断层以东至土坡组露头区域太原组发育较稳定的中厚煤层及部分不稳定的厚煤层,煤种为无烟煤,全区可采煤层预测资源量约3.8亿t,此外在深井预测区以西大范围掩盖区也可能赋存可观的煤炭资源,如果上述两区资源量得以证实,将会改变对香山含煤区煤炭资源的评价。 相似文献
16.
The Ruhr coal basin is part of the external fold and thrust belt of the Variscan orogen in Central Europe. Information from extensive coal mining, outcrops in the south of the Ruhr district, reflection seismic surveys and about 800 exploration boreholes in the north, support the interpretation of a mostly molasse-type sequence, more than 6000 m thick, of Namurian and Westphalian age. Both the southwest-northeast trending sedimentary basin structures and the fold structures of the Ruhr Carboniferous were caused by the compressive regime of the Variscan folding in its hinterland, but there is no direct relationship between sedimentary basin structures and the later folding structures. Coal formation started in the Namurian C, reached its maximum during the Westphalian A and B and ended during the Westphalian D. In total, about 250 coal seams were formed, but only 50 of them are of economic importance at present.Strata thicknesses and coal content are generally greater in the southeast of the Ruhr coalfield than in the northwest. An important exception can be observed in the lower part of the Westphalian A, where, in contrast, strata thicknesses are greatest in the northwest (in the Münsterland region), although the coal content remains the greatest in the southeast.Detailed isopach maps covering 100–200 m thick stratigraphic intervals reveal the existence of a southwest-northeast trending zone of reduced subsidence in the Ruhr coalfield that moved from southwest-northeast during the Westphalian. This structure can be interpreted as a peripheral bulge. Coal seems are purer and thicker in the area of this structure, which therefore must have been a paleogeographic element within the Ruhr basin.The general effect of a general decrease in the coal content of the Upper Carboniferous towards the northwest is superimposed on the migration of the coal content maxima of individual formations towards the northwest. During the Namurian C and Westphalian A the coal content maxima were situated in the area of the River Ruhr and during the Westphalian B and C in the area of the River Lippe.The deformation of the Ruhr coal basin is of post-Westphalian age, as demonstrated by the concordant folding of the Devonian and Carboniferous strata. The tectonic structure is mainly characterised by the following elements: stockwerk tectonics, axial elevations and a succession of compressional and extensional tectonics.Due to the general dip of the Ruhr coal basin towards the north, different structural levels (“stockwerks”) can be observed. The southern area displays the lowermost stockwerk, with many minor folds of about constant wavelength and low amplitudes. Thrusts are mainly small and some of them show increasing displacement upwards. The central part of the mining area displays the intermediate stockwerk with large, tight anticlinoria with minor folds separated by open synclines. These are accompanied by folded northwest- and southeast-vergent thrusts. In the northern Ruhr district, high anticlines and broad, trough-shaped synclinoria with only few thrusts represent the uppermost stockwerk. Large fold controlled thrusts die out at this level. Axial culminations and depressions have strongly influenced the structural style of the folding as well.According to this model of stockwerk tectonics, excess volume created by disharmonic folding is redistributed by thrusts. Thrusts dying out downwards at different stratigraphic and structural levels give evidence that there is no regional basal detachment below the Ruhr coal basin. This interpretation fits very well to new results achieved by the deep seismic reflection profile DEKORP 2-N. The section clearly shows thick-skinned tectonics in the Rhenish massif, with a shortening of the whole thickness of crust. The Ruhr coal basin can, therefore, be interpreted in terms of an autochthonous foreland basin in front of a buried thrust front to the south.Investigations on the post-Carboniferous strata of the Ruhr basin indicate different periods of active faulting. Cross and diagonal faults were formed partly at the end of the Variscan folding and partly before and during deposition of the Zechstein strata. A further important period of tectonic movements occurred during the early Kimmerian phase in the Late Triassic. Furthermore, earlier extensional faults in the Ruhr basin have been affected by Late Cretaceous transpression. 相似文献
17.
R.A. Facer 《Tectonophysics》1981,74(3-4)
A section 300 m thick across the Permian—Triassic boundary has been sampled in the Southern Coalfield of the Sydney Basin, New South Wales. 55 samples, mainly grey to drab sandstones, were collected from 9 diamond drill holes which penetrated the entire Narrabeen Group and the upper part of the conformably underlying Illawarra Coal Measures, as well as a sill emplaced into the coal measures. The samples included fully oriented cores. Additional reconnaissance samples from two further drill holes were also studied.Partial alternating field demagnetization and petrography indicate the magnetic remanence to be a stable DRM. Partial thermal demagnetization above 300°C or 400°C caused large increases in magnetic susceptibility. Partial chemical demagnetization did not cause significant changes in remanence directions.For the Coal Cliff Sandstone (basal Narrabeen Group, Triassic) the palaeomagnetic pole position (Normal) was calculated to be at 59°N 322°E (dp = 27°, dm = 29°), which agrees with previously published data. For the uppermost coal measures (Permian) the pole position was calculated as 58°N 340°E (dp = 09°, dm = 10°). Data for samples from the lower to middle coal measures yield a pole position which is between the new Permian—Triassic pole position and that for the underlying Middle Permian igneous rocks. The top of the Reversed “Kiaman Magnetic Interval” (Permian) may be near the Tongarra coal and Appin Formation boundary — (early) Late Permian. 相似文献
18.
A.G. Rodnikov 《Tectonophysics》1973,20(1-4):105-114
Results of seismic investigations in the transition zone from the Asian Continent to the Pacific Ocean are reported in detail. At the bottom of the sedimentary sequence presumably Cretaceous rocks are found in depressions of the sea floor. The “granitic” layer in the transition zone consists of igneous-sedimentary rocks in different stages of granitization. The “basaltic” layer is developed irregularly in thickness and seismic velocities; its origin is obscure. Apparently the earth's crust in the transition zone is still under formation. 相似文献
19.
20.
Stephen F. Greb Cortland F. Eble Donald R. Chesnut Jr. 《International Journal of Coal Geology》2002,50(1-4)
More than 130 Mt of Pennsylvanian coal is produced annually from two coal fields in Kentucky. The Western Kentucky Coal Field occurs in part of the Illinois Basin, an intercratonic basin, and the Eastern Kentucky Coal Field occurs in the Central Appalachian Basin, a foreland basin. The basins are only separated by 140 km, but mined western Kentucky coal beds exhibit significantly higher sulfur values than eastern Kentucky coals. Higher-sulfur coal beds in western Kentucky have generally been inferred to be caused by more marine influences than for eastern Kentucky coals.Comparison of strata in the two coal fields shows that more strata and more coal beds accumulated in the Eastern than Western Kentucky Coal Field in the Early and Middle Pennsylvanian, inferred to represent greater generation of tectonic accommodation in the foreland basin. Eastern Kentucky coal beds exhibit a greater tendency toward splitting and occurring in zones than time-equivalent western Kentucky coal beds, which is also inferred to represent foreland accommodation influences, overprinted by autogenic sedimentation effects. Western Kentucky coal beds exhibit higher sulfur values than their eastern counterparts, but western Kentucky coals occurring in Langsettian through Bolsovian strata can be low in sulfur content. Eastern Kentucky coal beds may increase in sulfur content beneath marine zones, but generally are still lower in sulfur than mined Western Kentucky coal beds, indicating that controls other than purely marine influences must have influenced coal quality.The bulk of production in the Eastern Kentucky Coal Field is from Duckmantian and Bolsovian coal beds, whereas production in the Western Kentucky Coal Field is from Westphalian D coals. Langsettian through Bolsovian paleoclimates in eastern Kentucky were favorable for peat doming, so numerous low-sulfur coals accumulated. These coals tend to occur in zones and are prone to lateral splitting because of foreland tectonic and sedimentation influences. In contrast, Westphalian D coal beds of western Kentucky accumulated during low differential tectonic accommodation, and therefore tend to be widespread and uniform in characteristics, but exhibit higher sulfur values because they accumulated in seasonally drier paleoclimates that were unfavorable for peat doming. Hence, basin analyses indicate that many differences between the mined coals of Kentucky's two coal fields are related to temporal changes in paleoclimate and tectonic accommodation, rather than solely being a function of marine influences. 相似文献