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Finite element modelling of reinforced concrete structuresHanna, Youssef G. (Youssef Ghaly) January 1983 (has links)
No description available.
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Constitutive modeling of reinforced concrete for nonlinear finite element analysis賀小崗, He, Xiaogang. January 1999 (has links)
published_or_final_version / Civil Engineering / Doctoral / Doctor of Philosophy
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Post-crack and post-peak behavior of reinforced concrete members by nonlinear finite element analysisWu, Yi, 吳奕 January 2006 (has links)
published_or_final_version / abstract / Civil Engineering / Doctoral / Doctor of Philosophy
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Micro-cracking and crack growth in notched concrete and mortar beamsGill, Laurence Mark 05 February 2015 (has links)
A dissertation submitted to the Faculty of Engineering, University of the
Wttwatersrand, Johannesburg, in fulfilment of th e degree of Master of
science in Engineering
Johannesburg 1988 / This dissertation addresses the question of the fracture
behaviour of notched concrete and mortar beams.
The major purpose of the work was to study the development
of the micro-cracked zone and identify the point
at which main crack growth began, and thus to characterise
concrete and mortar at the start of main crack
growth.
Notched concrete and mortur beams of width 100 mm,
depth either 200 mm or 300 nun, and with a span/depth
ratio of three, were tested. Measurements of midspan
deflection, midspan load, surface displacements across
the fracturing section and ultrasonic pulse transit
time were made. Ordinary Portland cement and mineral
aggregates were used for the concrete and mortar
beams.
The J'■integral, surface displacements across the fracturing
section and ultrasonic pulse transit time measurements
were used to detect the onset of main crack
growth. It was found that a reduction in the load carrying
capacity of concrete and mortar is possible due
to micro-cracking only. The value of the J-integral
at the start of main crack growth was found to be essentially
the same for concrete and mortar. The value
of the J-integral at the start of micro-cracking was
■ <
found to be essentially the same for concrete and
mortar, and about 40% of the value of the J-integral
at the start of main crack growth. The value of the
J-integral at the start of micro-cracking and at the
start of main crack growth was found, on average, to
increase for an increase in beam depth.
Surface displacements across the fracturing section
showed the tension zone at the start of main crack
growth to be approximately twice the size of the compression
zone for both concrete and mortar. The'size
of the micro-cracked zone, as determined from surface
displacements across the fracturing section, was found
to be 42% of the residual ligament depth for concrete,
and 41% of the residual ligament depth for mortar.
Scatter in the results was found to be considerable,
thus meaning that only general trends could be identified
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Behaviour of concrete under generalized biaxial loadingsFerdjani, Aissam January 1987 (has links)
No description available.
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Concrete cracking control in underwater marine structures using basalt fiberQuispe, C., Lino, D., Rodríguez, J., Hinostroza, A. 05 February 2021 (has links)
The construction of coastal ports requires the use of materials that meet the demands of the marine environment, to prevent underwater concrete structures from cracking and spalling easily; basalt fiber is used to delay the expansion of concrete and prevent the formation of cracks. This research studies the behavior of concrete for prefabricated piles with Portland Cement Type I and basalt fibers added in 0.1%, 0.3% and 0.6%; the results indicate that the fiber is suitable for concrete, the slump decreases, the compressive strength increases for specimens cured in tap water and sea water, the relationship between resistances does not vary, and the depth of carbonation decreases.
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Behaviour of concrete under generalized biaxial loadingsFerdjani, Aissam January 1987 (has links)
No description available.
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Prediction of low temperature cracking of asphalt concrete mixtures with thermal stress restrained specimen test resultsKanerva, Hannele K. 21 June 1993 (has links)
Low temperature cracking is attributed to tensile stresses induced in an
asphalt concrete pavement that develop when the pavement is subjected to a cold
temperature. Cracking results in poor ride quality and a reduction in service life of
the pavement. Low temperature cracking has been predicted by regression
equations, mechanistic approaches and by simulation measurements. The purpose of
the study reported herein is to (1) evaluate the Thermal Stress Restrained Specimen
Test (TSRST) as an accelerated performance test to simulate low temperature
cracking of asphalt concrete mixtures and (2) develop a deterministic and
probabilistic model to predict low temperature cracking with TSRST results.
Construction histories, cracking observations and temperature data were
collected for five test roads in Alaska, Pennsylvania and Finland. A full scale and
fully controlled low temperature cracking test program was conducted at the U.S.
Army Cold Regions Research and Engineering Laboratory (USACRREL).
Specimens were fabricated in the laboratory with original asphalt cements and
aggregates from the test roads. In addition, asphalt concrete pavement specimens
were cut from the test sections. The TSRST results obtained for these samples were
correlated with the field observations. Based on a statistical analysis of the data, the
TSRST fracture temperature is associated with the field cracking temperature and
crack frequency for the test roads where mixture properties dominated low
temperature cracking. It was concluded that the TSRST can be used to simulate low
temperature cracking of asphalt concrete mixtures.
A deterministic and a probabilistic model were developed to predict crack
spacing as a function of time using the TSRST results, pavement thickness and bulk
density, pavement restraint conditions and air temperature. The affect of aging on
pavement properties was incorporated in the models by predicting the field aging
with Long Term Oven Aging (LTOA) treatment in the laboratory. The calculation
of the crack spacing is based on the theory that the pavement slab cracks when the
pavement temperature reaches the cracking temperature of the mixture and the slab
is fully restrained. The deterministic model predicts crack spacing with time
whereas the probabilistic model predicts crack spacing and its variation with time
and yields the reliability of the design with regard to a minimum acceptable crack
spacing criterion defined by road authorities.
The models were verified by comparing the predicted crack spacings for the
five test roads to the observed crack spacings. The probabilistic model is
recommended for use in predicting the low temperature cracking of asphalt concrete
mixtures. / Graduation date: 1994
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Selection and performance evaluation of a test method to assess thermal cracking resistance of asphalt-aggregate mixturesJung, Duhwoe 30 July 1993 (has links)
Thermal distress in asphalt concrete pavements is a widespread problem around
the world. Thermal cracking can be divided into two modes of distress: low
temperature cracking and thermal fatigue cracking. Low temperature cracking results
from extremely cold temperatures; thermal fatigue cracking results from daily
temperature cycles.
Low temperature cracking is attributed to tensile stresses induced in the asphalt
concrete pavement as the temperature drops to an extremely low temperature. If the
pavement is cooled, tensile stresses develop as a result of the pavement's tendency to
contract. The friction between the pavement and the base layer resists the contraction.
If the tensile stress equals the strength of the mixture at that temperature, a micro-crack
develops at the surface of the pavement. Under repeated temperature cycles, the
crack penetrates the full depth and across the asphalt concrete layer.
The thermal stress restrained specimen test (TSRST) was identified as an
accelerated laboratory test to evaluate the thermal cracking resistance of asphalt concrete mixtures. The TSRST system developed at OSU includes a load system, data control/acquisition system and software, temperature control system, and specimen alignment stand. The overall system is controlled by a personal computer.
A TSRST is conducted by cooling an asphalt concrete specimen at a specified rate while monitoring the specimen at constant length. A typical thermally-induced stress curve is divided into two parts: relaxation and non-relaxation. The temperature at which the curve is divided into two parts is termed the transition temperature. The temperature at fracture is termed the fracture temperature and the maximum stress is the fracture strength.
An extensive number of TSRSTs over a wide range of conditions were performed to investigate the thermal cracking resistance of asphalt concrete mixtures. The TSRST results provided a very strong indication of low temperature cracking resistance for all mixtures considered. A ranking of mixtures for low temperature cracking resistance based on the TSRST fracture temperature was in excellent agreement with a ranking based on the physical properties of the asphalt cements.
It is highly recommended that the TSRST be used in mix evaluation to identify low temperature cracking resistance of asphalt concrete mixtures. The TSRST showed very promising results regarding the effect of all variables which are currently considered to affect the low temperature cracking of mixtures. The variables considered to have significant affect on the low temperature cracking resistance of mixtures in this study include asphalt type, aggregate type, degree of aging, cooling
rate, and stress relaxation. / Graduation date: 1994
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Tracking and detection of cracks using minimal path techniquesKaul, Vivek 27 August 2010 (has links)
The research in the thesis investigates the use of minimal path techniques to track and
detect cracks, modeled as curves, in critical infrastructure like pavements and bridges. We
developed a novel minimal path algorithm to detect curves with complex topology that may
have both closed cycles and open sections using an arbitrary point on the curve as the sole
input. Specically, we applied the novel algorithm to three problems: semi-automatic crack
detection, detection of continuous cracks for crack sealing applications and detection of crack
growth in structures like bridges. The current state of the art minimal path techniques only
work with prior knowledge of either both terminal points or one terminal point plus total
length of the curve. For curves with multiple branches, all terminal points need to be known.
Therefore, we developed a new algorithm that detects curves and relaxes the necessary user
input to one arbitrary point on the curve. The document presents the systematic development
of this algorithm in three stages. First, an algorithm that can detect open curves with
branches was formulated. Then this algorithm was modied to detect curves that also have
closed cycles. Finally, a robust curve detection algorithm was devised that can increase the
accuracy of curve detection. The algorithm was applied to crack images and the results of
crack detection were validated against the ground truth. In addition, the algorithm was also
used to detect features like catheter tube and optical nerves in medical images. The results
demonstrate that the algorithm is able to accurately detect objects that can be modeled as
open curves.
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