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The equivalent axle load based on fatigueZavaleta Loayza, Hugo Edmundo, 1947- January 1975 (has links)
No description available.
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Laboratory determination of resilient modulus of granular materials for flexible pavement designAlba, Jorge Luis 12 1900 (has links)
No description available.
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Correlation of resistance value (R-value) with California Bearing Ratio (CBR) for use in the design of flexible pavementsHashiro, Reyn S January 2005 (has links)
Thesis (M.S.)--University of Hawaii at Manoa, 2005. / Includes bibliographical references (leaves 97-102). / x, 102 leaves, bound ill. 29 cm
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Structural classification of granular base pavements using measured deflection bowl parametersJooste, Fritz Joubert 15 April 2014 (has links)
M.Ing. (Civil Engineering) / The: structural classification of granular base pavements by means of resilient deflection bowl parameters measured by the Impulse Deflection Meter and application of measured deflections at network level were investigated. The Investigation consisted of a mechanistic analysis and an analysis of observed field results. Curves for structural classification of granular base pavements obtained by regression are presented. The Curves obtained by the analysis of field observations compare well with local experience and theoretical failure criteria. It was found that the mechanistic model used in this study did not yield satisfactory results when simulating deflection behaviour through linear elastic programs. The parameters recommended for future use are Maximum Deflection (Y-rnax), Base Layer Index, or DLl (formerly SCI), Middle Layer Index, or MLl (formerly DOl) and Radius of Curvature. The use of deflection measurements at network level was also investigated. A method for calculating a Structural Stiffness Index to be incorporated into Pavement Management Systems as a Structural Indicator is proposed. Recommendations regarding the density of testing and identification of roads for testing at network level are also made. Several factors influencing deflections and structural bearing capacity are discussed and some recommendation." are made. The main factors influencing deflections and predicted pavement structural capacity were shown to be Temperature, Seasonal Influences and Condition of Surfacing. Further research into the specific influence of these factors on deflections and hearing capacity is needed.
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Research into the properties of lateritic gravels and their impact on pavement designNg'anjo, Peter 12 1900 (has links)
Thesis (M.Ing.)--Stellenbosch University, 2000. / ENGLISH ABSTRACT: Laterites are used extensively in the tropics as road building materials in unbound
base, sub-base layers and in surface layers. However, most base course specifications
usually require the provision of crushed and graded stone or stabilized base and often
exclude the general use of as-dug laterites or other naturally occurring gravels.
Various field studies in the past have clearly indicated that many lateritic gravel
deposits can be used successfully as base course materials in roads carrying low to
medium traffic without incurring additional maintenance costs and with considerable
cost savings in pavement construction rehabilitation.
Further research is needed for the more precise definition of the relationship between
laterite characteristics, traffic loading, environment, and pavement performance. In
this study, extensive use was made of static and cyclic triaxial testing to investigate
the fundamental behaviour of a lateritic gravel material. The tests produce information
for characterizing the shear strength, stress-strain properties and behaviour under
repeated loading. The gravel was sourced from stockpile at Malans Transport borrow
pit at Maaitjies Kuil near Cape Town. Testing was conducted on the material both as
granular material and stabilized with cement and foamed bitumen. Testing was done
under various conditions of stress, moisture and compaction. The resilient modulus of
the lateritic gravel was found to be affected by moisture and compaction apart from
the stress condition. Well known models were used to characterize the stressdependent
resilient modulus. A model for prediction of permanent deformation was
developed which together with the resilient modulus model were applied to the design
of a light pavement structure composed of lateritic gravel base. / AFRIKAANSE OPSOMMING: Lateriete word wydverspreid gebruik in die trope as 'n padbou materiaal. Die
materiaal word gebruik in ongebonde kroonlae, stutlae en oppervlaklae. Die meeste
spesifikasies vir kroonlae vereis dat gegradeerde gebreekte klip of gestabiliseerde
materiaal in die kroonlaag gebruik word. Die spesifikasies maak nie voorsiening vir
lateriet en gruis wat natuurlik voorkom nie. Verskeie veldstudies in die verlede het
duidelik getoon dat lateritiese materiaal met sukses gebruik kan word in die kroonlae
van paaie wat ligte tot medium verkeer dra. Lateriete kan gebruik word sonder
addidionele onkoste vir instandhouding en daar is merkbare kostebesparings wanneer
plaveisels rehabiliteer word.
Die verhouding tussen lateriet eienskappe, verkeerslas, omgewingsinvloede en
plaveisel werkverrigting moet beter gedefinieer word deur verdere navorsing. In
hierdie studie is omvattend gebruik gemaak van eenmalige en herhaalde belasting
drie-assige toetse om die fundamentele gedrag van lateritiese materiaal te definieer.
Hierdie toetse se resultate lewer inligting oor die skuifsterkte, spanning-vervorming
eienskappe en gedrag onder herhaalde belasting.
Die gruis wat gebruik is, is verkry vanaf 'n materiaalopslag by die leengroef van
Malans Transport te Maaitjies Kuil naby Kaapstad. Die materiaal is getoets as
granulêre materiaal en gestabiliseer met sement en skuim-bitumen. Die toetse is
gedoen onder verskillende toestande van spanning, voginhoud en verdigting.
Daar is bevind dat die veerkragtigheidmodulus van die lateritiese gruis nie net deur
die aangewende spanning beïnvloed word nie, maar ook deur die voginhoud en
verdigting van die materiaal. Welbekende modelle is gebruik om die spanningsafhanklike
gedrag van die materiaal te karakteriseer. 'n Model is ook ontwikkel om
die permanente vervorming van die materiaal te voorspel. Die twee modelle vir die
veerkragtigheidsmodulus en permanente vervorming is gebruik om 'n ligte
plaveiselstruktuur mee te ontwerp wat 'n lateritiese kroonlaag bevat.
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Calibration of discrete element modelling parameters for bulk materials handling applicationsGuya, Solomon Ramas January 2018 (has links)
A dissertation submitted in fulfilment of the requirements for the degree of Master of Science in Engineering to the Faculty of Engineering and the Built Environment, School of Mechanical, Industrial and Aeronautical Engineering, University of the Witwatersrand, Johannesburg , 2018 / The Discrete Element Method (DEM) models and simulates the flow of gran
ular material through confining geometry. The method has the potential to
significantly reduce the costs associated with the design and operation of bulk
materials handling equipment. The challenge, however, is the difficulty of
determining the required input parameters. Previous calibration approaches
involved direct measurements and random parameter search. The aim of this
research was to develop a sequential DEM calibration framework, identify ap
propriate calibration experiments and validate the framework on real flows in
a laboratory-scale silo and chute.
A systematic and sequential DEM calibration framework was developed. The
framework consists of categorising the DEM input parameters into three cat
egories of determining the directly measured input parameters, obtaining the
literature acquired input parameters, and linking physical experiments with
DEM simulations to obtain the calibrated parameter values. The direct mea
surement parameters comprised the coefficients of restitution and the particle
to wall surface coefficient of rolling friction. Literature obtained parameters
were the Young’s Modulus and Poisson’s ratio. The calibrated parameters
comprised the particle to wall surface coefficient of sliding friction calibrated
from the wall fiction angle, the particle to particle friction coefficients (sliding
and rolling) calibrated from two independent angles of repose, particle den
sity calibrated from bulk density, and adhesion and cohesion energy densities.
The framework was then tested using iron ore with a particle size distribution
between +2mm and - 4.75 mm in LIGGGHTS DEM software.
i
Validation of the obtained input parameter values in the silo and chute showed
very good qualitative comparisons between the measured and simulated flows.
Quantitative predictions of flow rate were found to be particularly sensitive
to variations in the particle to particle coefficient of sliding friction. It was
concluded that due to their inherent limitations, angle of repose tests were not
totally reliable to calibrate the particle to particle coefficient of sliding friction.
Sensitivity tests conducted showed that in the quasi-static flow regime, only
the frictional parameters were dominant, while both the frictional and colli
sional parameters were dominant in the dynamic flow regime. These results are
expected to lay a solid foundation for further research in systematic DEM cali
bration and greatly increase the effectiveness of DEM models in bulk materials
handling applications. / XL2019
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A mechanistic-empirical design model for unbound granular pavement layersTheyse, Hechter Luciën 25 March 2010 (has links)
D.Ing. / Unbound granular material has and is still being used with great success in the construction of road pavements in South Africa and many other countries around the world. Often this material is used in the main structural layers of the pavement with very little protection provided against high traffic induced stresses by way of a surface treatment or thin asphalt concrete layer. The performance of unbound granular pavement layers depend mainly on the level of densification and degree of saturation of the material in addition to the stress levels to which the layers are subjected. The main form of distress of unbound granular layers is the permanent deformation of the layer, either through the gradual deformation or rapid shear failure of the layer. Design engineers need accurate and appropriate design procedures to safeguard the road against such rapid shear failure and to ensure that the road has sufficient structural capacity to support the traffic loading over the structural design period. The recent trend in pavement design has been to move away from empirical design methods towards rational mechanistic-empirical design methods that attempt to relate cause and effect. Although a mechanistic-empirical pavement design method has been available in South Africa since the midseventies, increasing criticism has been levelled against the method recently. The models for characterising the resilient response and shear strength and estimating the structural capacity of unbound material have been of particular concern. The purpose of the research reported in this thesis was therefore to develop an improved mechanistic-empirical design model, reflecting the characteristics and behaviour of unbound granular material. The new design model consists of three components namely a resilient modulus, yield strength and plastic deformation damage model with each model including the effects of the density and moisture content of the material unbound granular where appropriate. The models were calibrated for a range of unbound materials from fine-grained sand and calcrete mixture to commercial crushed stone products using the results from static and dynamic tri-axial tests. An approximation of the suction pressure of partially saturated unbound material was introduced in the yield strength model and was validated with independent matric suction measurements on the sand and calcrete mixture. The yield strength model which is a function of the density and moisture conditions as well as the confinement pressure was calibrated for the individual materials with a high accuracy. A single plastic strain damage model was calibrated for the combined plastic strain data from all the crushed stone materials but a single model could not be calibrated for the plastic strain data of the natural gravels as these materials vary too much in terms of particle size distribution and the properties of the fines found in these materials. The formulation of the plastic strain damage model includes the density and degree of saturation of the material. A single resilient modulus model was calibrated for the combined resilient modulus data from all the materials excluding the data from a limited number of tests during which large plastic strain occurred. The resilient modulus model again ii incorporates the density, degree of saturation and the stress dependency of unbound granular material and is on an effective stress formulation for the bulk stress. Finally, the yield strength, resilient modulus and plastic strain damage models are combined in a mechanistic-empirical design model for partially saturated unbound granular material. Results from the proposed design method seem more realistic than results from the current design model and the model is not as sensitive to variation in the design inputs as the current design model is. In addition to this, the effects of the density and moisture content of the partially saturated, unbound granular material on the resilient response and performance of the material is explicitly included in the formulation of the proposed design model.
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Vibratory hammer compaction of granular materialsChilukwa, Nathan Ntanda 03 1900 (has links)
Thesis (MScEng)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: Compaction is one of the key processes in the construction of road pavement layers. Not only
is it significant in ensuring the structural integrity of the material in the road layers, but it also
has an influence on the engineering properties and performance of the soil material. A poorly
compacted material is characterised by low density, high porosity and below standard shear
strength. This, as a result causes rutting, moisture susceptibility, potholing, corrugations and
passability problems on the road. Therefore, it is vitally important that field compaction is
done correctly. For this reason, laboratory compaction methods have been developed to
simulate the field compaction process in the laboratory.
The Mod AASHTO test has long been used as the laboratory compaction method of choice
by virtue of its simplicity and the lack of bulky equipment required. However, previous
studies have established that the Modified AASHTO method does not adequately simulate
field compaction criteria especially for cohesionless materials. Two reasons have been
advanced;
The Mod AASHTO compaction method does not adequately simulate the compaction
done in the field when the granular mix is laid;
The compaction method may cause disintegration of the material.
Alternative tests have been considered and much research has focused upon the use of a
modified demolition hammer (vibratory hammer) for laboratory compaction of granular
materials.
This study undertook to evaluate the influence of test factors pertinent to the vibratory
hammer compaction method. The influence of these test factors on compaction time and
obtainable material density was assessed with the objective of developing a compaction
method for granular materials. Vibratory hammer compaction tests were conducted on G3
hornfels, G4 hornfels and G7 sandstone material types and to a lesser extent, reclaimed
asphalt (RA). Densities obtained were referenced to Mod AASHTO compaction density.
Findings of the study showed that, the mass of the tamping foot has a significant influence on
the obtainable compaction density. Other factors such as, moisture content, frequency and
frame rigidity were also found to affect compaction with the vibratory hammer. In addition, it
is shown that the surcharge load does not significantly influence the obtainable compaction density but does contribute to the confinement of the material and restricts the upward bounce
of the hammer.
On the basis of the results and findings, a compaction method was proposed, incorporating
test parameters and factors that would provide ideal results for a set compaction time.
Repeatability tests showed that, the developed vibratory hammer compaction method was
effective in compacting graded crushed stone material types (i.e. G3 and G4) and probably
RA. The test was not as effective on the G7 material. Further studies on this material (G7) are
required.
In addition to the previous testing regime, a comparative assessment of the developed
vibratory hammer compaction method in relation to the vibratory table method was done. The
results show that the vibratory hammer is capable of producing specimens of densities
comparable to those of the vibratory table.
A sieve analysis undertaken before and after compaction showed that compaction with the
developed vibratory hammer compaction method does not result in any significant material
disintegration.
Based on the results of this study, a specification for the determination of maximum dry
density and optimum moisture content of granular material using the vibratory hammer is
recommended. / AFRIKAANSE OPSOMMING: Kompaksie is een van die belangrikste prosesse in die konstruksie van die padplaveisel. Dit is
nie net waardevol vir die versekering van strukturele integriteit van die materiaal, maar dit
het ook 'n invloed op die ingenieurseienskappe en vermoë van die grond materiaal. 'n Swak
gekompakteerde materiaal word gekenmerk deur 'n laë digtheid, hoë porositeit, on
onvoldoende skuifweerstand. Die kenmerke maak die material vatbaar vir vogen. Lei tot
spoorvorming, slaggate, golwe en deurgangs probleme op die pad. Dit is dus uiters
noodsaaklik dat veld kompaksie korrek gedoen word. Om hierdie rede, is kompaksie metodes
in die laboratorium ontwikkel om sodaend veldkompaksie te simuleer.
Die “Mod AASHTO” laboratorium kompaksie toets is die gekose laboratorium kompaksie
metode op grond van sy eenvoudigheid en gebruik van minimale toerusting. Vorige studies
het egter bevestig dat die “Mod AASHTO”-metode nie veldkompaksie akkuraat kan simuleer
nie, veral vir kohesielose materiaal. As gevolg van twee hoofredes;
Die Mod AASHTO kompaksiemetode is nie ‘n realistiese en vergelykende simmulering
van kompaksie soos dit in die veld gedoen word nie;
Die kompaksie metode mag verbrokkeling van die materiaal veroorsaak.
Alternatiewe toetse was oorweeg en baie navorsing het gefokus op die gebruik van 'n
aangepaste vibrerende hamer.
Hierdie studie het onderneem om verskeie relevante toetsfaktore van die vibrerende hamer en
hul invloed op die kompaksie en verkrygbare digtheid te bestudeer. Die invloed van hierdie
toetsfaktore op kompaksietyd en verkrygbare materiaal digtheid was geassesseer met die doel
om 'n kompaksiemetode vir granulêre materiaal te ontwikkel.
Vibrerende hammer kompaksietoetse was uitgevoer op G3 hornfels, G4 hornfels en G7
sandsteen materiaal en tot 'n mindere mate herwinde asfalt. Digthede verkry was verwys na
die Mod AASHTO kompaksie digtheid. Resultate van die studie het getoon dat die gewig van
die stamp voet ‘n merkwaardige invloed het op die verkrygbare kompaksie digtheid. Ander
faktore soos voginhoud, frekwensie en raam styfheid het ook getoon om kompaksiedigtheid
te beïnvloed met die vibrerende hammer. Benewens was ook getoon dat die toeslaglading
geen beduidende invloed het op die verkrygbare kompaksie digtheid nie, maar wel bydrae tot
die inperking van die materiaal en verhoed die vertikale terugslag van die hammer. Gebaseer op die resultate en bevindinge was ‘n kompaksiemetode voorgestel wat toets
parameters integreer met toetsfaktore en tot volg ideale resultate vir ‘n gegewe kompaksietyd
voorsien. Herhaalde kalibrasie toetse het getoon dat die ontwikkelde kompaksiemetode
effektief is in die kompaktering van gegradeerde gebreekte klip materiaaltipes (G3 en G4) en
moontlik herwanne asfalt. Die toets was nie so doeltreffend op die G7 materiaal nie. Verdere
studies op hierdie materiaal (G7) is dus nodig.
Addisioneel tot die vorige toets, is bevind dat ‘n vergelykende assesering van die ontwikkelde
vibrerende hammer kompaksiemetode in verhouding tot die vibrerende tafel. Die resultate
wys dat die vibrerende hammer die vermoë het om toetsmonsters met digthede vergelykbaar
met die vibrerende tafel te produseer.
Sifanalise voor en na kompaksie het getoon dat verdigting met die ontwikkelde vibrerende
hamer kompaksie metode nie lei tot die disintegrasie van die materiaal nie. Gebasseer op die
resultate van dié studie was ‘n spesifikasie vir die bepaling van maksimum droé digtheid en
optimale voginhoud van granulêre material aangeraai.
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Highway earthwork and pavement production rates for construction time estimationKuo, Yao-chen 28 August 2008 (has links)
Not available / text
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Matric suction response of unbound granular base materials subject to cyclic loadingCraciun, Ovidiu, Engineering & Information Technology, Australian Defence Force Academy, UNSW January 2009 (has links)
The emergence of analytically-based pavement design has encouraged investigations toward a better understanding of the behaviour of pavement layers under cyclic loading. Unbound granular base (UGB) materials are commonly placed as base course layers in the design of pavement foundations. Due to their nature and geometry they are unsaturated geo-materials and therefore, it is desirable to study their behaviour using the framework of unsaturated soil mechanics. Current literature reflects very limited achievements in this direction. This thesis presents the development of a cyclic triaxial testing system and associated testing methodology that meets the challenges of testing an UGB material as an unsaturated soil. The testing system enables the initialisation of a specimen to target matric suction and facilitates direct measurement of its evolution under cyclic loading. In conjunction with the use of accurate on-specimens strain measurement transducers, ???clean??? strain and matric suction cyclic responses are obtained. Two types of cyclic triaxial testing are investigated: with constant cell pressure (i.e., CSeries testing) and with varying (cyclic) cell pressure where both axial and radial stress components are simultaneously (and in phase) pulsed (i.e., V-Series testing). Different initial matric suctions, si will be imposed in the testing program and the influence of si on material behaviour is analysed. This is investigated in a similar manner for C- and V-Series testing. The influence of si appears to be significant for both cyclic and permanent strain responses. A strong stress path dependency is found to characterise the behaviour of the UGB material. Under a wide range of cyclic deviator stress magnitudes, permanent strain response is found to correlate with that of matric suction response. Both appear to indicate better the relative performance of a UGB material than the response of resilient modulus. Another particular aspect investigated is the influence of additional fines on the behaviour of the UGB material. To ???isolate??? the effects of additional fines the cyclic and permanent strain responses of ???equivalent??? specimens with equivalent compaction and unsaturation condition, but different fines content, are compared. The results showed that the relative performance of the two materials (distinguished by the different percentage of fines content) in intertwined with the strong stress path dependency. It is also found that a material compacted at higher dry density may not improve its behaviour under cyclic loading, but may worsen with load cycles. Soil-water characteristic curve tests are conducted for the UGB materials investigated, showing high sensitivity of initial matric suction to moisture content, which increases further for the material with additional fines. This explains the notion of ???sensitivity??? of UGB materials as commonly suggested by practicing pavement engineers.
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