Spelling suggestions: "subject:"groundwater -- bthermal properties"" "subject:"groundwater -- 3thermal properties""
1 |
Interpretation of the thermal behavior of groundwater in an alluvial terrace : Bonneville Dam, Columbia Gorge, OregonMalin, Richard Stephen 01 January 1991 (has links)
Groundwater temperature data, collected at an alluvial terrace located on the Oregon shore of the Columbia River downstream from Bonneville Darn, was analyzed in order to characterize and formulate a conceptual model of the thermal data for the groundwater system in the terrace. There is concern that an unlined entrance channel for a new navigation lock, to be located down the middle of the terrace, will widen the range of temperatures in the fish hatchery-groundwater supply. The analysis of temperature behavior in the terrace supports the hydraulic observations derived from analysis of pump test data, but with greater definition of the more subtle behavior of the groundwater system not readily discernible in the pump test data. The thermal behavior of the terrace groundwater system is governed by: 1) the stratigraphy of the terrace, 2) its groundwater recharge characteristics, 3) thermal influence from the Columbia River, and 4) stress placed on the aquifer system due to pumping of fish hatchery wells located in the terrace.
|
2 |
A geological and hydrogeological study of the Shu Shu thermal springs, KwaZulu-Natal.Gravelet-Blondin, Kent Royson. 11 September 2014 (has links)
The Shu Shu thermal springs are located in central KwaZulu-Natal in South Africa at an altitude
of 250m above mean sea level at the bottom of the Tugela Valley. They have been investigated
in an attempt to ascertain whether or not they possibly share a common origin with fifteen other
springs which are located in a north-northwestern trending, 1000km long zone within the
eastern interior of the country. They have also been studied to establish if they potentially
represent a viable and sustainable geothermal energy resource that may be developed in the
future.
Isotope ratios confirm that the thermal springs are meteoric in origin, and are likely recharged
within a 130km long band located to the west toward the Great South African Escarpment.
These waters then descend vertically to a depth of approximately 1827m – 2153m, at which
point the fractures along which they move close due to escarpment-associated confining
pressure. It is a reduction in this self-same confining pressure along the coastal plain, which
occurs due to the continual removal of overburden, which forces the thermal water to migrate
toward the east along ever-more opening fractures. Due to a slightly elevated geothermal
gradient of 3.1°C / 100m at depth, this groundwater reaches a temperature of approximately
75°C – 85°C as it traverses toward the Shu Shu thermal springs over a time period of > 61
years (at present).
The geochemical signature of the Shu Shu thermal waters is derived through leaching
from the basement rocks through which they pass, with elevated concentrations of Na, K, Ca,
Mg, Fe, Al, Si, F, Sr and SO₄ detected. Once below the floor of the Tugela Valley, at a depth of
approximately 990m, the thermal groundwater commences its ascent, likely along the west-southwest
– east-northeast orientated thrusts and associated fractures of the Tugela Terrane of
the Natal Metamorphic Province. However, the thermal waters abut against those brittle
structures trending north-northwest – south-southeast, which are perpendicular to the axis of
least principle compressive stress, and so are ultimately forced to rise within the Shu Shu
thermal springs.
Prior to surfacing, the temperatures of these waters drop to approximately 67°C as a result of
natural, conductive cooling processes. However intermixing with shallow, cold groundwater,
which is discernible through geochemical and isotopic variations, and atmospheric impacts,
further cool the thermal waters to a surfacing temperature of approximately 50°C. Nevertheless, a binary cycle geothermal energy power plant remains a possibility. Although thermal efficiency
and volume flow rate values are favourable, heat transfer values are low and require further
investigation through exploratory drilling. Nevertheless, the establishment of a 400kW power
plant, should it occur, will typically be sufficient to service 625 rural homes. / Thesis (M.Sc.)-University of KwaZulu-Natal, Durban, 2013.
|
Page generated in 0.1173 seconds