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51	Centrifuge and theoretical modelling of conical footings on sand Tan, Finian Seng Chin January 1990 (has links) No description available. 624.1 Foundations on sand
52	Sand as a complex system : inter-particle forces and granular matter Hutton, Sean, 1969- January 2002 (has links) Abstract not available Sand Particles Granular materials
53	Sand as a complex systeminter-particle forces and granular matter / Hutton, Sean,1969- January 2002 (has links) For thesis abstract select View Thesis Title, Contents and Abstract Sand Particles Granular materials
54	Developmental history of European beachgrass (Ammophila arenaria (L.) Link) plantings on the Oregon coastal sand dunes / Green, Diantha Louise. January 1965 (has links) Thesis (M.S.)--Oregon State University, 1965. / Typescript. Includes bibliographical references (leaves 47-50). Also available on the World Wide Web. Sand dunes. Shore protection
55	A conceptual approach to subterranean oil sand fragmentation and slurry transport Lam, S.C. Anthony 11 1900 (has links) Oil sand deposits are found at three depths; shallow, intermediate, and deep. Shallow deposits are processed by surface mining while deep deposits are processed using thermal extraction methods. There are currently no production methods to extract oil sand at intermediate depths. The motivation for this research is to demonstrate the technical applicability of methods to access oil sand that is too shallow for thermal extraction methods and too deep for economical surface mining. This work consisted of developing a system concept as a method for accessing, fragmenting, and removing oil sand at intermediate depths. A technical analysis and a cost estimate were also performed. In addition, the applicability of a comparative methodology was demonstrated with case studies. A key gap in the understanding of how to implement the system concept is tooling design and power requirements for fragmenting oil sand and interburden; and so a set of laboratory experiments was conducted to investigate the power required to cut oil sand. Oil sand blocks were formed from oil sand samples for the experiments. These blocks underwent various tests to examine their characteristics. Tests included: shear testing, extraction testing, porosity measurements, and scanning electron microscopy. Lab-scale experiments were conducted in dry, wet, and frozen conditions in support of the fragmentation aspect of the system concept. Thermal imaging was used to qualitatively view temperature variation during the testing process and cutter wear was viewed using a digital microscope. Results were compared against a steady-state cutting model with recommendations for future work. oil sand subterranean underground
56	Effects of Sand on the Components and Performance of Electric Submersible Pumps Carvajal Diaz, Nicolas 1985- 14 March 2013 (has links) The increasing world demand for oil has pushed oil companies to extract it from the ocean at extreme depths. With the increase in depth comes an increase in operation costs, especially the deep-sea equipment changeover cost. To be able to push the oil to the ocean surface, Electrical Submersible Pumps (ESPs) are commonly used as artificial lift. The changeover cost of these pumps in deep-water has been estimated to sometimes be as much as forty times the cost of a new pump. One common reason for the failure of ESPs is the erosion and abrasion created by the fine sands that seep through the gravel pack mesh in the well hole. These fine sand particles are most destructive to the bearings and bushings due to their capability to enter the clearances lubricated by the pumped fluid. Over time, the sustained abrasion and erosion in the different components of the ESP will affect the performance of the pump and could lead to its damage. This work describes the design, construction and evaluation of an erosion test rig built at the facilities of the Turbomachinery Laboratory in Texas A&M University. The test rig is capable of introducing 100 mesh (6 mil) sand into the flow loop, measure its concentration and separate it at the exit with minimal water loss. The pump under study is a Baker Hughes 10.25" WJE1000. The performance of the pump is described by measuring the head, flow rate, power and efficiency. The pump is equipped with accelerometers to detect the casing vibration as well as proximity probes in five locations along the pump to detect the internal vibrations of the shaft near the bearings as well as impeller radial movement. The baseline data, to be used for comparison with the worn out pump, has been shown and recommendations for the study method and operation of the rig are given. Sand Erosion ESP
57	Numerical simulation on the formation of sand wave by internal solitary waves Liao, Bo-Chih 26 March 2011 (has links) In the last few years, internal waves have been extensively studied by many scholars, mostly focused on the physical property and the effect on ecology and geochemistry. The geological influence, however, was rarely discussed. By EK500 and 3.5 kHz sub-bottom sonar system, it is reported that many sand waves exist in the South China Sea at 600 meter water depth. Internal waves are a very important driving mechanism in the South China Sea. Its movement over the marine bed causes unsteady flow field disturbance. In order to clarify whether the internal wave is the main factor to form sand wave, we conduct a series of numerical simulations. Most studies on the formation of sand waves are mainly in the nearshore area. Due to the difficulty in observation, only very few special discussions consider depth of 500 meters or deeper. First of all, in this thesis, we use the Korteweg de Vries (KdV) equation to derive wave and current in an internal soliton. Then, the flow field is substituted into the Regional Ocean Modeling System (ROMS) numerical model to simulate the three-dimensional movement of internal waves and the associated movement of suspended sediment in order to discuss the mechanism of sand wave formation. Finally, the variation of wavelengths of sand wave is analyzed and compared with in-situ measurement. From the simulation result, the internal wave causes the formation of sand waves. After the passage of dozens of internal waves, a flat sea floor will gradually form sand wave topography. Different depth and slope of the sea bottom will affect the sand wave wavelength also. sand wave internal wave
58	Stability of granular mixtures Berry, Donald Stilwell, January 1900 (has links) Thesis (Ph. D.)--University of Michigan, 1936. / Caption title. Thesis note on label attached to p. [1]. "1935 Preprint ... American society for testing materials ... 75." Road materials. Sand.
59	The effects of restraining boundaries on the passive resistance of sand results of a series of tests with a medium-scale testing apparatus. Report submitted to the Office of Naval Research, Dept. of the Navy, Tschebotarioff, Gregory P. Johnson, Edmund G., January 1953 (has links) Edmund G. Johnson's Thesis (M.S.)--Princeton. / "Project No. Nr-081-117. Contract No. Nonr-100 9(00)." Bibliography: leaf 112. Earth pressure. Sand.
60	Deposition and stratification of oblique dunes, South Padre Island, Texas Weiner, Stephen Paul, January 1981 (has links) (PDF) Thesis (M.A.)--University of Texas at Austin, 1981. / Vita. Includes bibliographical references (leaves 128-130). Sand dunes Geomorphology

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