Consistency limits and compaction characteristics of clay soils containing rubber waste

Soltani, Amin; Deng, An; Taheri, Abbas; Sridharan, A.

doi:10.1680/jgeen.18.00042

Cited by 26 publications

(21 citation statements)

References 54 publications

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“…It is worth drawing attention to the fact that results of presented tests can be compared with only one paper, in which authors also were carrying out UU triaxial tests on specimens of kaolinite clay and kaolinite clay-crumb rubber mixtures [31]. In both cases, for rubber waste there are similar values of angle of internal friction −27.5° for powder and 28.7° for granulate (in this study) and 19°-26° for crumb [31] as well as cohesion-1.7 kPa for powder and 6 kPa for granulate (in this study) and 1-5 kPa for crumb [24]. Tajdini et al [31], in mixtures with kaolin, were using crumb-type waste in two size ranges: 2-5 mm (marked by symbol G30) and 1-3 mm (marked by symbol G80) and with three weight contents: 5%, 10%, and 15%.…”

Section: The Effect Of Rubber Waste On the Shear Strength Parametersmentioning

confidence: 59%

“…In the case of powder, the relationship was inverse: shear stresses were higher for a greater powder content (P-25). The report from Tajdini et al's [24] study did not comprise the information on changes of failure shear stress in terms of G30 or G80 content. Obviously, although the conditions of this study were close to those of Tajdini et al [24], they were not identical.…”

Section: Analysis Of Shear Strength Test Resultsmentioning

confidence: 99%

“…The report from Tajdini et al's [24] study did not comprise the information on changes of failure shear stress in terms of G30 or G80 content. Obviously, although the conditions of this study were close to those of Tajdini et al [24], they were not identical. Basic differences included: another soil type, no saturation with water before presented tests, another type of rubber waste, higher decrease of cohesion in (RCR) mixtures, and perhaps a different mineralogical composition of soils (Tajdini et al [31] did not provide the mineralogical composition of kaolinite clay).…”

Section: Analysis Of Shear Strength Test Resultsmentioning

confidence: 99%

“…The majority of research carried out on waste is directed primarily towards checking their influence on a change of the optimum moisture content in soils [17,18], on the mechanical behavior of soils [19][20][21][22][23], on the reduction of Atterberg's limits and plasticity index of fine-grained soils [21,[24][25][26], and on the reduction of natural soils swelling [16,[27][28][29][30]. If the first two groups of issues apply to all soils, then the next two are strictly related to cohesive (frequently expansive) soils.…”

Section: Literature Reviewmentioning

confidence: 99%

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Strength Characteristics of Clay-Rubber Waste Mixtures in UU Triaxial Tests

Jastrzębska

2019

Geosciences

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This paper presents results of undrained and unconsolidated (UU) triaxial tests related to the influence of tire waste addition on strength characteristics of red clay from Patoka in Southern Poland. Angle of internal friction and cohesion values were estimated for 30 specimens prepared from pure red clay (RC), its mixtures with two different fractions of shredded rubber in 5%, 10%, and 25% mass proportions as well as for pure powder (P) and granulate (G). It has been observed that the addition of granulate contributes more to the increase in the angle of friction than the addition of powder (uu = +1% (G-5) / +16% (G-10) / +31% (G-25), uu = +1% (P-5) / +10% (P-10) / +19% (P-25)). On the other hand, rubber additions reduce cohesion in mixtures, and the effect is enhanced with increases in their grain size and percentage composition (cuu = −31% (G-5) / −63% (G-10) / −87% (G-25), cuu = −67% (P-5) / −58% (P-10) / −58% (P-25)). It has been noticed that a change of parameters uu and cuu causes a decline of shear stresses at increasing granulate content. There is an inverse relationship for powder. At the same time, it has been shown that the failure strain, hence a change in red clay-rubber (RCR) mixtures plasticity, is related to the level of confining stress 3 and the type of rubber waste. Results of tests and their comparison with results of other researchers show that each time it is necessary to experimentally verify a given soil with specific rubber waste.

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Section: The Effect Of Rubber Waste On the Shear Strength Parametersmentioning

confidence: 59%

Section: Analysis Of Shear Strength Test Resultsmentioning

confidence: 99%

Section: Analysis Of Shear Strength Test Resultsmentioning

confidence: 99%

Section: Literature Reviewmentioning

confidence: 99%

See 2 more Smart Citations

Strength Characteristics of Clay-Rubber Waste Mixtures in UU Triaxial Tests

Jastrzębska

2019

Geosciences

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“…These impact forces can likewise be generated at transition zones involving abrupt variations of vertical track stiffness, such as at the approaches to tunnels, bridge or viaduct and level crossings, or where there is a sudden change from conventional ballast to slab track intensifying ballast breakage and adversely affecting track stability [11][12][13][14][15]. One potential method of enhancing the substructure capacity to withstand the large cyclic and impact loads induced by fast-moving heavy-haul trains is to improve the performance of the ballast layer using plastic (e.g., geogrids) and rubber inclusions (e.g., rubber mat, tire cell, and rubber crumbs) [2,[11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30].…”

Section: Introductionmentioning

confidence: 99%

Use of Geogrids and Recycled Rubber in Railroad Infrastructure for Enhanced Performance

Indraratna

Ngo

et al. 2019

Geosciences

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Railway tracks are conventionally built on compacted ballast and structural fill layers placed above the natural (subgrade) foundation. However, during train operations, track deteriorations occur progressively due to ballast degradation. The associated track deformation is usually accompanied by a reduction in both load bearing capacity and drainage, apart from imposing frequent track maintenance. Suitable ground improvement techniques involving plastic inclusions (e.g., geogrids) and energy absorbing materials (e.g., rubber products) to enhance the stability and longevity of tracks have become increasingly popular. This paper presents the outcomes from innovative research and development measures into the use of plastic and rubber elements in rail tracks undertaken at the University of Wollongong, Australia, over the past twenty years. The results obtained from laboratory tests, mathematical modelling and numerical modelling reveal that track performance can be improved significantly by using geogrid and energy absorbing rubber products (e.g., rubber crumbs, waste tire-cell and rubber mats). Test results show that the addition of rubber materials can efficiently improve the energy absorption of the structural layer and also reduce ballast breakage. Furthermore, by incorporating the work input parameters, the energy absorbing property of the newly developed synthetic capping layer is captured by correct modelling of dilatancy. In addition, the laboratory behavior of tire cells and geogrids has been validated by numerical modelling (i.e., Finite Element Modelling-FEM, Discrete Element—DEM), and a coupled DEM-FEM modelling approach is also introduced to simulate ballast deformation.

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