جستجوی مقالات مرتبط با کلیدواژه "پتانسیل رمبندگی" در نشریات گروه "عمران"

Collapsibility is the sudden volume change of the soil due to the increase degree of saturation. This phenomenon occurs in sands due to the grains sliding on each other and in clays due to the loss of electron bonds between particles. The percentage of soil collapsibility depends on various conditions such as soil type, mineral composition, moisture percentage, dry weight, stress applied during wetting, and the amount of initial soil moisture increase. This paper has been conducted to investigate the effect of nanomaterials on soil collapsibility potential. The soil was selected from the Allahabad region of Kerman in south east of Iran with a high loamy index. For this purpose, Nano-silica, Nano-clay, aluminum Nano-oxide, and Calcium-Nano-Carbonated additives with percentages of 0.5, 1, 1.5, and 2% were used to improve the soil. Double consolidation and direct shear tests were the two main criteria for evaluating the performance of nanomaterials. The results showed that the collapsibility index of the desired soil due to the addition of Nan- clay compared to the addition of calcium Nano-Carbonate, Nano silica, and aluminum oxide causes a greater decrease in the collapsibility index. Furthermore, the results obtained from the SEM images indicate that the collapsible soil has microscopic and macroscopic holes, which the addition of an additive destroys larger holes and creates a correlation between soil particles. This problem reduces the amount of collapsibility index.

Collapsible soils are one of the moisture sensitive soils that experience sudden and significant settlements due to wetting. These soils are widely distributed and constitute about 10% of the total land area of the world, which are typically located in arid and semi-arid areas. In foundation engineering, the most important issue in dealing with these soils is to measure their collapse potential with different water infiltration patterns. The effect of parameters such as initial soil conditions, loading conditions and gradation quality on the behavior of these soils has been investigated. The amount of clay in the soil is considered as an important factor in the behavior of the collapsible soils. Water enters the soil from different sources, but the existing devices and tests to measure the collapse potential are not capable of modeling water infiltration patterns. In this study, an apparatus was used that simulates different water infiltration patterns based on the direction of water movement (from top or bottom) and type of water distribution (point or wide). The results show that in oedometer tests and tests with the ability to simulate the water infiltration patterns, with the increase in the amount of clay in the sample, the collapse potential increases, but the amount of increase is not the same in different tests. The amount of increase in collapse potential due to the increase of clay in the sample is greater in single and double oedometer tests than in tests with the ability to simulate the water infiltration patterns, and for a more accurate prediction of the collapse potential, tests with the ability to simulate the water infiltration patterns should be used. Among the different water infiltration patterns in the soil, for the sample with clay compared to the sample without clay, the highest increase in collapse potential is related to the top-point water infiltration pattern ) and the lowest increase is related to the bottom-wide water infiltration pattern( ). But for the sample with 23% clay compared to the sample without clay, the highest increase in collapse potential is related to the top-wide water infiltration pattern( ) and the lowest increase is related to the bottom-wide water infiltration pattern.

Collapsible soil as an example of problematic soils can cause problems in structures. Collapsible soil may be stable before the presence of water, but after water enters, it experiences significant and sudden settlement. The most important issue in dealing with these soils is to predict their settlement. Up to now, various experiments have been designed in the laboratory or in-situ to determine the collapse potential, the most common of which is the oedometer test. The most important drawback of the existing experiments is the impossibility of simulating the pattern of water infiltration in the soil. In this study, an apparatus with a mold with a diameter of 14 cm and a height of 10 cm was built that has the ability to simulate water infiltration patterns and can measure the amount of collapse potential based on the source of water infiltration. This apparatus simulates water infiltration patterns into four categories based on the direction of water movement (from top to bottom or from bottom to top) and water distribution (point or expanding). The laboratory results of this apparatus on a sample of collapsible soil show that the collapse potential depends on the water infiltration pattern and it isn’t possible to use one collapse potential amount for all patterns. According to the laboratory results, the highest collapse potential is related to the pattern of water infiltration from top to bottom and expanding form, and the lowest is related to the pattern of water infiltration from bottom to top and point form.

Collapse soils have a stable loose honeycomb-type structure in a low degree of saturation which is susceptible to a large reduction in total volume or collapse upon wetting. The aim of this study is to evaluate the collapse potential and shear strength parameters due to saturation of soil caused by the infiltration of contaminants including leachate wastewater and chemicals into the soil. Since the separation of leachate components is difficult, especially with change of ingredients and pH in long time, the two factors sulfuric acid and sodium hydroxide were used as representatives of the leachate in the pH of 1 to 14. Furthermore, collapse tests and direct shear tests were performed on soil samples which were saturated by leachate. Experimental results show that leachate with a low pH or acidic solutions increase the soil collapse potential; on the other hand, leachate with a high pH or alkaline solutions cause less soil collapse. Variation range of soil collapse in acidic solution was much more than alkaline solution. Direct shear test results demonstrate that acidic leachate increase the soil cohesion and reduce the internal friction angle of soils; however, alkaline leachate reduce the soil cohesion and increase the friction angle of soils.

The eect of suction on consolidation behavior has a dominant role to play in the constitutive modeling of unsaturated soils, and, therefore, has received the researchers attention in this eld. In this paper, the eect of the initial conditions of compacted specimens of a clayey soil on their consolidation behavior, under saturated and unsaturated states, is investigated. After determining the compaction curve of the soil, the samples were statically compacted at dierent initial suctions and void ratios (moisture content, dry densities). In order to investigate the volume change behavior of collapsible soils, the cylindrical samples were loaded to a denite stress in conventional oedometer apparatus. Then, while keeping the vertical stress constant, the volume changes of samples due to wetting were measured. After completion of the collapse settlements, the stepped loading of the samples was continued and the end of the primary consolidation line of the samples were attained. The saturated normal consolidation lines of samples with dierent initial water contents and dry densities are compared. It is shown that the normal consolidation line is almost unique and its position is not aected by the initial condition of the samples. This result suggests a simple method for predicting the collapse potential under dierent conditions. The method can be described as follows: The eective stress after saturation is calculated. The initial void ratio (before saturation) subtracted from the void ratio of the soil in a saturated normal consolidation line, corresponding to the eective vertical stress at saturation, would be the change of void ratio due to saturation. The collapse settlements could then be easily calculated. Since determination of the saturated normal consolidation line is a conventional and inexpensive procedure, the proposed method can be regarded as a versatile and inexpensive technique for forecasting the collapse potential.

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Collapsible soils are soils that compact and collapse after they get wet. The soil particles are originally loosely packed and barely touch each other before moisture soaks into the ground. As water is added to the soil in quantity and moves downward، the water wets the contacts between soil particles and allows them to slip past each other to become more tightly packed. Water also affects clay between other soil particles so that it first expands، and then collapses like a house of cards. Another term for collapsible soils is «hydrocompactive soils» because they compact after water is added. The amount of collapse depends on how loosely the particles are packed originally and the thickness of the soil that becomes wetted. Collapsible soils consist of loose، dry، low-density materials that collapse and compact under the addition of water or excessive loading. These soils are distributed throughout the southwestern United States، specifically in areas of young alluvial fans، debris flow sediments، and loess (wind-blown sediment) deposits. Soil collapse occurs when the land surface is saturated at depths greater than those reached by typical rain events. This saturation eliminates the clay bonds holding the soil grains together. Similar to expansive soils، collapsible soils result in structural damage such as cracking of the foundation، floors، and walls in response to settlement. Collapsible soils may be suspected in undeveloped areas that have young، accumulating sandy and silty soils in dry areas. The soils may be confirmed to be collapsible through engineering testing. These tests include study of seismic waves through the soils، rates of drilling through the soils (blow counts)، and testing undisturbed soil samples obtained by careful drilling for compaction after wetting. In this study، the ability of Artificial Neural Networks (ANN) has been investigated to determine the collapse potential of soils. Therefore، different samples of collapsible soil have been collected from an area (Zahedan plain). General tests were performed on the samples in the laboratory and 130 samples of collapsible soil from different depths and locations were recorded in the database. The collapse potential tests (One-dimensional collapse test) was carried out on the samples and with the aim of further investigations، the grain size distribution، specific gravity، atterberg limits and strength properties of the samples were performed. In the later stages، the collapsible samples data were prepared for the artificial neural networks input. After the network training process and the subsequent learning، some network models have been selected under experiments، which include six inputs and one output. According to the predicted results، it was indicated that the correlation between experimental and predicted data by the ANN is 95%. Furthermore، the results show that artificial neural networks can predict collapse potential of soils، also the calculations and required tests will be reduced due to their simple use and inexpensive tests.