جستجوی مقالات مرتبط با کلیدواژه "anzali sand" در نشریات گروه "عمران"

Nowadays, given to the scarcity of Oil and Gas resources onshore, and the increasing demand for construction of facilities in coastal areas the use of deep foundations for providing stability for marine infrastructures, such as Oil and Gas Drilling Rigs and Wind turbines, has gained an increasing attraction. Interests in research of helical piles have been arisen due to the advantages of such foundations. Physical modelling is one of the most common method in practice for performance evaluation of deep foundations which provides with the researcher the capability of repeatability. In addition, it is chip and easy-to-execute method compared to the in-situ pile loading tests. Frustum confining vessel (FCV), is one of the most effective tool for physical modeling approach. FCV has a conical shape, which can convert the vertical applied pressure to the base of the vessel, to horizontal stress and to produce a stress distribution similar to the idealized linear stress distribution of soil in situ. Consequently, each base pressure corresponds to a specific embedment depth in real-world. In this study, a new FCV device with an optimized dimensions with the capability of testing model piles in saturated soil samples was constructed. To the best of the author’s knowledge, the newly constructed apparatus is the only FCV with this capability. After performance evaluation of the device, the load-displacement of a helical pile with one and three helices at different relative densities, both in wet and saturated sand, was evaluated. Results indicate that as the relative density increases the interlocking of the sand and helices increases which yields to an increase in the ultimate bearing capacity of pile. On the other hand, the bearing capacity reduces significantly in saturated sands. Also, increasing the number of helices significantly increases the bearing capacity of the helical pile.

In this experimental research, the effect of the number of micropiles, the relative density of soil, and dry stone surcharge on the liquefaction potential of Anzali sand was studied by using shaking table apparatus with the rigid transparent container. The inner sides of the rigid transparent box, installed on the shaking table, were covered with the sheets of foams to reduce generation and reflection of body waves from the rigid sides. Two pore pressure transformers (PPT) were used to monitor the pore water pressure variations. For model preparation, the moist tamping method was used. The grouting operation for the construction of micropiles was performed using a grouting device under the injection pressure of 0.1 bar with a water-cement ratio of 0.5. Three different arrangements of micropiles were used. The equivalent diameter and the length of micropiles were 0.9 and 23 cm, respectively. After 7 days of curing, the model was saturated from the bottom of the tank with a low hydraulic gradient. All models were shaken under a harmonic sinusoidal load with the frequency, the displacement amplitude, and the duration of 3Hz, 0.9 cm and 9.5 seconds, respectively. It was observed by increasing the relative density of the sand, due to reducing of void ratio, the values of excess pore water pressure ratio (ru) were decreased, and the required cycles for reaching the ru,max (Npeak) were increased. The obtained results showed that the liquefaction potential of saturated sand was significantly decreased by installing two and four micropiles into the soil model. On the other hand, one micropile had a negligible effect on reducing of the liquefaction potential. It can be explained by forming the grout-sand zone around the micropiles and also the localized compaction in the soil after grouting, the rate of pore water pressure generation is limited. A dry stone surcharge with the stress of 1.2 kPa was placed on the surface of saturated sand, and due to the significant increase in effective stress, the liquefaction potential was reduced significantly, leading to the increase of Npeak. Based on the obtained results, the upper and lower bounds were proposed to predict the values of ru in pure and reinforced sand regarding the N/Npeak.

The presence of oil in the soil media, by changing theinteraction between soil particles, reduces the shearstrength of the soil compared with clean soil. Finally,oil pollution, reduces permeability, internal friction an-gle and bearing capacity and increases volumetric strainand the resulting settlement of the structure. On theother hand, most of the foundation analysis methodsrequire the use of subgrade reaction modules as a ba-sic parameter to assess elastic situation of the subgradeand determination of the sti ness and load-deformationbehavior of the soil. It should be noted that, subgradereaction modulus is obtained mainly through eld plateloading testing. In this study, using physical modelingwith plate loading, deformation behavior and sti ness ofoil-contaminated sand and reaction modulus for the dif-ferent percentages of oil contamination will be reviewed.The results can present a more appropriate estimate ofthe amount of elastic settlement of the structures restedon the contaminated soils, also re ne the amount of foot-ing's exibility on this group of soils. The most e ectiveparameters on the soils sti ness in this eld include thesoil classi cation, relative density, type of contamina-tion and the amount of contamination in the soil. Thesevariables can be e ective in the process of the possiblechanges of sti ness and soil reaction modulus. Gas oil,crude oil and kerosene have been used as contaminationmaterials. These liquids have been added into the sandin three di erent percent rates, 2, 4 and 6. The sandhas been compacted in three di erent situations; loose,medium and dense. Based on this research, oil contam-ination causes substantial decrease in soil sti ness andmore greasy oil contamination is even more e ective inreducing the soil subgrade reaction. In addition, densesoils sti ness is less sensitive to oil contamination e ects.These results can be used for investigating the sites inwhich there is a possibility of oil leakage to layers ofthe land. Results have been presented in the form ofempirical equations.

S‌i‌n‌c‌e t‌h‌e l‌a‌t‌e 1960s, s‌e‌v‌e‌r‌a‌l c‌o‌n‌s‌t‌i‌t‌u‌t‌i‌v‌e m‌o‌d‌e‌l‌s h‌a‌v‌e b‌e‌e‌n d‌e‌v‌e‌l‌o‌p‌e‌d f‌o‌r s‌a‌n‌d‌s d‌e‌s‌c‌r‌i‌b‌i‌n‌g t‌h‌e‌i‌r s‌t‌r‌e‌s‌s-s‌t‌r‌a‌i‌n ‌e‌h‌a‌v‌i‌o‌r. M‌o‌s‌t o‌f t‌h‌e‌s‌e m‌o‌d‌e‌l‌s w‌e‌r‌e e‌s‌t‌a‌b‌l‌i‌s‌h‌e‌d b‌a‌s‌e‌d o‌n a m‌e‌a‌s‌u‌r‌e o‌f t‌h‌e p‌l‌a‌s‌t‌i‌c w‌o‌r‌k a‌n‌d s‌o‌m‌e y‌i‌e‌l‌d c‌r‌i‌t‌e‌r‌i‌a, a‌m‌o‌n‌g t‌h‌e‌m b‌e‌i‌n‌g t‌h‌e L‌a‌d‌e-D‌u‌n‌c‌a‌n m‌o‌d‌e‌l. I‌t w‌a‌s i‌n t‌h‌e m‌i‌d 1980s w‌h‌e‌n t‌h‌e s‌t‌r‌e‌s‌s l‌e‌v‌e‌l c‌o‌n‌c‌e‌p‌t w‌a‌s f‌o‌u‌n‌d t‌o b‌e a‌n a‌p‌p‌r‌e‌c‌i‌a‌b‌l‌e f‌a‌c‌t‌o‌r c‌o‌n‌t‌r‌o‌l‌l‌i‌n‌g t‌h‌e b‌e‌h‌a‌v‌i‌o‌r o‌f s‌a‌n‌d‌s. T‌h‌e s‌t‌r‌e‌s‌s l‌e‌v‌e‌l i‌s d‌e‌f‌i‌n‌e‌d a‌s t‌h‌e c‌o‌n‌f‌i‌n‌i‌n‌g p‌r‌e‌s‌s‌u‌r‌e o‌r t‌h‌e v‌e‌r‌t‌i‌c‌a‌l s‌t‌r‌e‌s‌s o‌n a s‌h‌e‌a‌r p‌l‌a‌n‌e, w‌h‌i‌c‌h d‌i‌f‌f‌e‌r‌s f‌r‌o‌m p‌o‌i‌n‌t t‌o p‌o‌i‌n‌t i‌n a g‌r‌a‌n‌u‌l‌a‌r m‌e‌d‌i‌u‌m u‌n‌d‌e‌r a s‌y‌s‌t‌e‌m o‌f e‌x‌t‌e‌r‌n‌a‌l l‌o‌a‌d‌s. B‌a‌s‌e‌d o‌n t‌h‌i‌s c‌o‌n‌c‌e‌p‌t, a n‌u‌m‌b‌e‌r o‌f s‌t‌r‌e‌n‌g‌t‌h - d‌i‌l‌a‌t‌a‌n‌c‌y m‌o‌d‌e‌l‌s w‌e‌r‌e d‌e‌v‌e‌l‌o‌p‌e‌d f‌o‌r s‌a‌n‌d‌s. T‌h‌e s‌h‌e‌a‌r s‌t‌r‌e‌n‌g‌t‌h o‌f s‌a‌n‌d i‌s r‌e‌l‌a‌t‌e‌d t‌o t‌h‌e l‌e‌v‌e‌l o‌f s‌t‌r‌e‌s‌s a‌n‌d t‌h‌e t‌y‌p‌e o‌f t‌e‌s‌t i‌n w‌h‌i‌c‌h t‌h‌e s‌h‌e‌a‌r s‌t‌r‌e‌n‌g‌t‌h p‌a‌r‌a‌m‌e‌t‌e‌r‌s a‌r‌e m‌e‌a‌s‌u‌r‌e‌d. I‌n t‌h‌i‌s r‌e‌s‌e‌a‌r‌c‌h, t‌h‌e g‌e‌o‌t‌e‌c‌h‌n‌i‌c‌a‌l p‌r‌o‌p‌e‌r‌t‌i‌e‌s o‌f A‌n‌z‌a‌l‌i S‌a‌n‌d (l‌o‌c‌a‌t‌e‌d i‌n G‌u‌i‌l‌a‌n p‌r‌o‌v‌i‌n‌c‌e, n‌o‌r‌t‌h‌e‌r‌n I‌r‌a‌n, o‌n t‌h‌e c‌o‌a‌s‌t‌a‌l l‌i‌n‌e o‌f t‌h‌e C‌a‌s‌p‌i‌a‌n S‌e‌a) a‌r‌e i‌n‌v‌e‌s‌t‌i‌g‌a‌t‌e‌d, i‌n a‌c‌c‌o‌r‌d‌a‌n‌c‌e w‌i‌t‌h i‌t‌s s‌t‌r‌e‌n‌g‌t‌h -d‌i‌l‌a‌t‌a‌n‌c‌y b‌e‌h‌a‌v‌i‌o‌r. A‌s t‌h‌i‌s p‌a‌r‌t‌i‌c‌u‌l‌a‌r t‌y‌p‌e o‌f s‌a‌n‌d i‌s a‌b‌u‌n‌d‌a‌n‌t i‌n n‌o‌r‌t‌h‌e‌r‌n I‌r‌a‌n, s‌u‌c‌h r‌e‌s‌e‌a‌r‌c‌h a‌p‌p‌e‌a‌r‌s t‌o b‌e w‌o‌r‌t‌h‌w‌h‌i‌l‌e, a‌s m‌o‌s‌t s‌e‌i‌s‌m‌i‌c g‌e‌o‌t‌e‌c‌h‌n‌i‌c‌a‌l i‌n‌v‌e‌s‌t‌i‌g‌a‌t‌i‌o‌n‌s, a‌s w‌e‌l‌l a‌s o‌t‌h‌e‌r c‌o‌n‌v‌e‌n‌t‌i‌o‌n‌a‌l s‌t‌u‌d‌i‌e‌s, d‌e‌a‌l w‌i‌t‌h t‌h‌e s‌t‌r‌e‌n‌g‌t‌h o‌f t‌h‌i‌s s‌a‌n‌d. F‌o‌r e‌x‌a‌m‌p‌l‌e, t‌h‌e l‌i‌q‌u‌e‌f‌a‌c‌t‌i‌o‌n p‌o‌t‌e‌n‌t‌i‌a‌l a‌n‌d t‌h‌e p‌o‌s‌t - l‌i‌q‌u‌e‌f‌i‌e‌d b‌e‌h‌a‌v‌i‌o‌r o‌f A‌n‌z‌a‌l‌i S‌a‌n‌d a‌r‌e a‌l‌l b‌a‌s‌e‌d o‌n a s‌t‌r‌e‌n‌g‌t‌h -d‌i‌l‌a‌t‌a‌n‌c‌y m‌o‌d‌e‌l, t‌h‌e b‌e‌h‌a‌v‌i‌o‌r o‌f w‌h‌i‌c‌h w‌a‌s m‌e‌a‌s‌u‌r‌e‌d b‌y a n‌u‌m‌b‌e‌r o‌f d‌i‌f‌f‌e‌r‌e‌n‌t d‌i‌r‌e‌c‌t s‌h‌e‌a‌r t‌e‌s‌t‌s, a‌s t‌h‌e m‌o‌s‌t p‌o‌p‌u‌l‌a‌r a‌n‌d a‌v‌a‌i‌l‌a‌b‌l‌e t‌e‌s‌t‌s f‌o‌r s‌a‌n‌d. T‌h‌e d‌i‌l‌a‌t‌i‌v‌e b‌e‌h‌a‌v‌i‌o‌r o‌f A‌n‌z‌a‌l‌i S‌a‌n‌d w‌a‌s g‌e‌n‌e‌r‌a‌l‌i‌z‌e‌d t‌o c‌a‌p‌t‌u‌r‌e i‌t‌s r‌e‌l‌e‌v‌a‌n‌t p‌r‌o‌p‌e‌r‌t‌i‌e‌s. F‌i‌n‌d‌i‌n‌g‌s i‌n‌d‌i‌c‌a‌t‌e t‌h‌a‌t A‌n‌z‌a‌l‌i S‌a‌n‌d, a‌t l‌e‌a‌s‌t i‌n t‌h‌e d‌i‌r‌e‌c‌t s‌h‌e‌a‌r t‌e‌s‌t‌s; d‌o‌e‌s n‌o‌t s‌h‌o‌w a v‌e‌r‌y i‌n‌t‌e‌r‌p‌r‌e‌t‌a‌b‌l‌e b‌e‌h‌a‌v‌i‌o‌r, p‌o‌s‌s‌i‌b‌l‌y d‌u‌e t‌o i‌n‌h‌e‌r‌e‌n‌t e‌r‌r‌o‌r‌s w‌i‌t‌h‌i‌n t‌h‌e d‌i‌r‌e‌c‌t s‌h‌e‌a‌r t‌e‌s‌t, a‌l‌t‌h‌o‌u‌g‌h a r‌a‌t‌h‌e‌r r‌e‌a‌s‌o‌n‌a‌b‌l‌e r‌e‌l‌a‌t‌i‌o‌n‌s‌h‌i‌p b‌e‌t‌w‌e‌e‌n t‌h‌e p‌e‌a‌k a‌n‌d c‌r‌i‌t‌i‌c‌a‌l s‌t‌a‌t‌e f‌r‌i‌c‌t‌i‌o‌n a‌n‌g‌l‌e‌s w‌a‌s f‌o‌u‌n‌d a‌s f‌u‌n‌c‌t‌i‌o‌n‌s o‌f t‌h‌e s‌t‌r‌e‌s‌s l‌e‌v‌e‌l a‌n‌d t‌h‌e d‌e‌n‌s‌i‌t‌y i‌n‌d‌e‌x.