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Sensitivities of channel geometry compared to modeling assumptions in dam failure analysisWindham, Joseph Michael 10 December 2010 (has links)
This research includes a sensitivity analysis of channel geometry and model assumptions in 1 dimensional (1D) dam break analysis. The specific modeling assumptions that are analyzed include, breach development time, breach width, and breach side-slopes. The question always arises when doing 1D dam break modeling of how detailed does the geometry data need to be to answer the subject question within an acceptable tolerance. LIDAR data and bathymetric data used for channel characteristic add significant detail to the model geometry as opposed to using course gridded data such as the USGS 10 meter Digital Elevation Models (DEMs). However, as geometry detail increases so does model development time, model run time, and cost to retrieve data. This research analyzes the level of error introduced in model results from accuracy of channel geometry as compared to the level of error introduced from assumption made in breach characteristic.
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Dynamic evaluation of hydraulic elastomeric mountsEnslin, J. 06 December 2011 (has links)
M.Phil. / This study identifies and evaluates dynamic models used to characterise the dynamic stiffness and phase angle of hydraulic elastomeric mounts that are primarily used as engine and operator cab isolators in vehicular applications. Linear models developed for hydraulic elastomeric mounts are analysed for their suitability to be used to characterise the dynamic stiffness and its phase angle in the low and high frequency range. A sensitivity analysis provides insight into the parameters with a high level of sensitivity to changes in model parameters. The models selected from the linear analysis are enhanced and updated by performing a quasi-linear analysis to compensate for the dynamic behaviour of certain parameters. Non-linear dynamic behaviour of the decoupler is also investigated. These models are then verified experimentally. To set-up an analytical model that can be used to predict the dynamic characteristics of the hydraulic elastomeric mount it is necessary to develop a physical model from which the system differential equations are extracted. From the physical model flow continuity equations and fluid momentum equations are developed to obtain an expression that describe the fluid response in the inertia track and decoupler respectively. Lumped parameter mechanical models are developed next from which equivalent differential equations are derived to describe the internal dynamics of the hydraulic mount. These differential equations along with the transmitted force equation directly derived from the physical model are used to develop the dynamic stiffness transfer function. Time domain input displacement and output transmitted force data are taken at a specific frequency and amplitude, and are used to generate hysteresis loops to extract the dynamic stiffness and phase angles. For most of the computational effort, both analytical and experimental, MATLAB programs are written to perform curve fitting, FFT calculation, numerical integration and dynamical simulation. Emphasis is placed on the dynamic considerations of hydraulic mount design in the automotive industry and where machines are subjected to shock and vibration. The results and techniques used to model and the mounts are useful to designers in the field of shock and vibration isolation. Finally, the aim of the work is to keep the dynamic models as simple as possible, to be used effectively in the identification of the structural dynamic characteristics of hydraulic elastomeric mounts. To avoid complexity two models are used to describe the dynamics of the mount, one model for the low frequency, large amplitude conditions and one for the high frequency, small amplitude conditions. The information is then used to determine how the mount will respond under certain dynamical conditions.
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High Pressure Hydraulic Supply System ModelMock, William H. 01 January 1977 (has links) (PDF)
A mathematical model is derived to provide quasi-steady state predictions of the performance of a high pressure hydraulic supply system, using equations which govern the physical processes as opposed to equations which match input-output characteristics. Model equations are developed to describe the operation of the power source, control valves, energy source, gas side of the system, hydraulic accumulator, the motorpump, and hydraulic side of the system. The accuracy of the model is then checked by inserting known parameters from a previously developed control system and comparing model predictions with performance data from this system.
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Propagation of a hydraulic fracture with tortuosity : linear and hyperbolic crack lawsKgatle, Mankabo Rahab Reshoketswe January 2016 (has links)
A thesis submitted to the Faculty of Science, University of the Witwatersrand, Johannesburg, in fulfilment of the requirements for the degree of Doctor of Philosophy. Johannesburg, 2015. / The propagation of hydraulic fractures with tortuosity is investigated. Tortuosity is the
complicated fracture geometry that results from asperities at the
fluid-rock interface and,
if present, from contact regions. A tortuous hydraulic fracture can either be open without
contact regions or partially open with contact regions. We replace the tortuous hydraulic
fracture by a two-dimensional symmetric model fracture that accounts for tortuosity. A
modified Reynolds
flow law is used to model the tortuosity in the
flow due to surface
roughness at the fracture walls. In order to close the model, the linear and hyperbolic
crack laws which describe the presence of contact regions in a partially open fracture
are used. The Perkins-Kern-Nordgren approximation in which the normal stress at the
crack walls is proportional to the half-width of the symmetric model fracture is used. A
Lie point symmetry analysis of the resulting governing partial differential equations with
their corresponding boundary conditions is applied in order to derive group invariant solutions
for the half-width, volume and length of the fracture. For the linear hydraulic
fracture, three exact analytical solutions are derived. The operating conditions of two of
the exact analytical solutions are identified by two conservation laws. The exact analytical
solutions describe fractures propagating with constant speed, with constant volume and
with
fluid extracted at the fracture entry. The latter solution is the limiting solution of
fluid extraction solutions. During the
fluid extraction process,
fluid
flows in two directions,
one towards the fracture entry and the other towards the fracture tip. It is found
that for
fluid injection the width averaged
fluid velocity increases approximately linearly
along the length of the fracture. This leads to the derivation of approximate analytical
solutions for
fluid injection working conditions. Numerical solutions for
fluid injection
and extraction are computed. The hyperbolic hydraulic fracture is found to admit only
one working condition of
fluid injected at the fracture entry at a constant pressure. The
solution is obtained numerically. Approximate analytical solutions that agree well with
numerical results are derived. The constant pressure solutions of the linear and hyperbolic
hydraulic fracture are compared. While the hyperbolic hydraulic fracture model is
generally considered to be a more realistic model of a partially open fracture, it does not
give information about
fluid extraction. The linear hydraulic fracture model gives various
solutions for di erent working conditions at the fracture entry including
fluid extraction.
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The flow of water in transition sections of rectangular open channels at supercritical velocitiesWilson, Warren Elvin 01 July 1940 (has links)
No description available.
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Local scour at isolated obstacles on river bedsHuang, Cheng-Chang 30 August 1990 (has links)
Maximum equilibrium scour depths, equilibrium scour volumes,
and induced equilibrium movements at isolated obstacles on river
beds were investigated in clear-water scour. The research was
achieved by a systematic flume study based on the results of
dimensional analysis of local scour.
The main tested obstacles for local scour were cubes. Local
scour at a circular cylinder of aspect ratio 1 and a sphere were
also examined for comparison with scour at cubes. Each obstacle was
placed on a flat movable bed and oriented normal to the incident
flow. Non-cohesive uniform medium sand and very fine gravel were
used as movable beds. The tested flow conditions were controlled to
give many combinations of the relevant dimensionless parameters for
local scour: the flow Froude Number, relative obstacle size, and
relative roughness of bed material.
Water surface profiles and longitudinal velocity profiles along
the plane of symmetry, as well as the horizontal velocities near the
bed around isolated obstacles on a fixed bed were examined in
several runs. For a slightly submerged cube, the path of maximum
velocity downstream of the cube moves from the water surface into
the lower part of the flow. At a greater distance downstream, the
path of maximum velocity tends to move upward toward the water
surface. An increase of flow Froude Number leads to a hydraulic
jump behind the cube. The relative longitudinal velocity near the
bed is increased in this region. The decrease of relative water
depth or the increase of flow Froude Number can lead to increased
average relative horizontal velocity (V/u) near a cube. The cube
has the highest average V/u value, as compared to flow near a
circular cylinder and a sphere.
The local scour processes and equilibrium scour patterns at
isolated cubes on movable beds were also examined. There is not a
unique equilibrium scour pattern for clear-water scour at a cube on
a movable bed. Equations were developed to predict the maximum
equilibrium scour depth and scour volume and the critical condition
for incipient motion of bed material at a cube in clear-water scour.
As the water becomes relatively deep, the shape effect of the
circular cylinder and the sphere become negligible. The major
equilibrium movement of a cube on a movable bed due to scour
involves longitudinal displacement, vertical settlement, and
longitudinal inclination. Equations were developed to predict the
equilibrium movement and the critical condition for incipient
upstream movement of a cube in clear-water scour. / Graduation date: 1991
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Development of a hydraulic bone chamber implant to study in vivo bone repair and adaptationFoust, Richard John 08 1900 (has links)
No description available.
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Modeling channel erosion in cohesive streams of the Blackland Prairie, Texas at the watershed scaleCapello, Stephanie V. Allen, Peter M., January 2008 (has links)
Thesis (M.S.)--Baylor University, 2008. / Includes bibliographical references (p. 61-67)
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Axial flow forces on spool type hydraulic valvesMueller, James Paul, January 1965 (has links)
Thesis (M.S.)--University of Wisconsin--Madison, 1963. / eContent provider-neutral record in process. Description based on print version record. Bibliography: l. 73-74.
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A theoretical and experimental study of hydraulic power supplies using pressure-compensated pumps, their influence on servosystem dynamic response, and thier [sic] utilization in energy-saving configurations /Pery, Arie January 1983 (has links)
No description available.
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