جستجوی مقالات مرتبط با کلیدواژه « scale effect » در نشریات گروه « عمران »

Raft foundations usually have a high bearing capacity in sand, but the amount of settlement limit the allowable bearing pressure. Nowadays, the employment of piled rafts foundations as a solution for decrease of settlement is common. In such cases, the raft usually carries a high portion of structural loading, and the piles are as the settlement reducer elements. The number of piles and their configuration are determined that settlement of the foundation decreases to an allowable value. In these situations, the configuration of piles is determined in optional manner and strategically. In a piled raft foundation, pile-soil-raft interaction is complicated. Although several numerical studies have been carried out to analyze the behaviors of piled raft foundations, very few experimental studies are reported in the literature. This paper concentrates on study of behavior of piled raft in sand by physical modeling and finite element analysis method. The piles and raft models were made of cast-cast-in-place concrete. The physical models consisted of single pile, single pile in group, unpiled raft and piled raft foundation. The size effects of the models were investigated. The results showed that with installation of the single pile in the group, the pile bearing capacity and stiffness increase. Due to increase of the number of piles beneath the raft, the bearing capacity of raft increase and its settlement decrease, significantly. With the use of finite element method and the critical state theory, one can predicate behavior of test model in the full scale dimensions.

Rainfall Runoff modeling especially in ungauged watersheds is almost dependent on hydro-geomorphologic data. In this regard, the effects of data and DEM resolution on deriving watershed’s geomorphologic data such as subbasins area, channels and subbasins’ slope should be well realized in modeling. In this research, HEC-HMS as the rainfall runoff model and two subbasins with different areas, geomorphologic properties and climate were selected for studying. By reducing the cell size of the DEM derived from a topo map, simulated peaks increased. For DEM cell sizes less than 100 m, the differences in simulated peak were limited to 2 to 5%. Using SRTM DEMs against the topo DEM at the scale of 1:25000, representing the effects of data resolution in rainfall runoff modeling, led to obtaining higher flood peaks at the two watersheds. Such an outcome was obtained for time to peak, hydrograph base time, and the slope of hydrograph rising limb. Change of SRTM DEM resolution affected the model output more than the case of using topo DEM. Decreasing DEMs resolution by decreasing information content of the topo DEM reduced differences in the model output when using two different sources of DEM. Furthermore, it is concluded that the extent of scale effect in modeling could not be inferred by watershed size. It was illustrated that HEC-HMS application in a watershed of more diversity was more sensitive to data resolution. Using cell size of 100 m and less could guaranty the result of the HEC-HMS application regardless of DEM origin and size of watersheds. Rainfall Runoff modeling especially in ungauged watersheds is almost dependent on hydro-geomorphologic data. In this regard, the effects of data and DEM resolution on deriving watershed’s geomorphologic data such as subbasins area, channels and subbasins’ slope should be well realized in modeling. In this research, HEC-HMS as the rainfall runoff model and two subbasins with different areas, geomorphologic properties and climate were selected for studying. By reducing the cell size of the DEM derived from a topo map, simulated peaks increased. For DEM cell sizes less than 100 m, the differences in simulated peak were limited to 2 to 5%. Using SRTM DEMs against the topo DEM at the scale of 1:25000, representing the effects of data resolution in rainfall runoff modeling, led to obtaining higher flood peaks at the two watersheds. Such an outcome was obtained for time to peak, hydrograph base time, and the slope of hydrograph rising limb. Change of SRTM DEM resolution affected the model output more than the case of using topo DEM. Decreasing DEMs resolution by decreasing information content of the topo DEM reduced differences in the model output when using two different sources of DEM. Furthermore, it is concluded that the extent of scale effect in modeling could not be inferred by watershed size. It was illustrated that HEC-HMS application in a watershed of more diversity was more sensitive to data resolution. Using cell size of 100 m and less could guaranty the result of the HEC-HMS application regardless of DEM origin and size of watersheds.

Determination of the rock mass strength is a challenge for geotechnical engineers. Some part of this problem is related to complex interaction of rock mass components, intact rock and discontinuities, and the other part is related to difficulty in determination of the mechanical properties of intact rock and discontinuities. The common approach to determine the mechanical properties of rocks is undertaking laboratory experiments and extrapolate the insitu properties based on these laboratory experiments. This extrapolation, or in the other word size effect, has been remained as a challenge for practical rock engineers for decades. Size effect studies can be divided into two groups of one dimensional scale effect, in which the diameter of samples is fixed and the length of samples are changed, and three dimensional scale effect, in which the ratio of length to diameter, called slenderness ratio, is fixed and the diameter is changed. Review of previous studies on the effect of slenderness ratio on the strength of intact rock shows that in some studies as the slenderness increases up to specific value, the strength decreases while in other studies the slenderness ratio has no significant effect on the strength. Results of previous studies on the effect of sample diameter on the strength of intact rock are also inconclusive. Some studies show that as the diameter of sample increases, the strength decreases while other studies show the increase of strength up to specific diameter or no scale effect. This paper aims to study both one dimensional and three dimensional size effect on intact rock properties. To this end, around 120 sandstone samples with diameter between 19 to 145 mm and slenderness ratio of 1 to 4 were prepared and uniaxial compression tests were carried out on these samples. Uniaxial compression tests were carried out using MTS 815. Axial and circumferential extensometers were used to measure deformation of samples during experiments. Results of this study show that the increase of diameter up to 50 mm resulted in the increase of uniaxial compressive strength and no scale effect was observed for diameters greater than 50 mm. This trend was observed for all slenderness ratios. No scale effect was observed on the elastic modulus and the Poisson’s ratio. Therefore, the minimum diameter of around 50 mm, which is suggested by ISRM and ASTM standards, is the size that scale has no effect on the results of uniaxial compression tests. It was found that the increase of slenderness ratio up to 2.5 results in the decrease of strength and no significant effect was observed for greater slenderness ratios. To find out the reason of observed behavior, failure mechanisms of samples at different slenderness ratios were studied. Four types of failure mode were observed in the experiments; generation of a single shear plane, multiple shear planes, shear plane with some cracks in the center of specimens and tensile cracks parallel to the loading direction. It was found that at low slenderness ratios, samples are failed by propagation of tensile cracks which results in higher strength compared to the other failure modes. Therefore, the higher strength of samples with slenderness ratio of 1 is related to this failure mechanism.

Regarding significant reduction in costs and operating problems, three-sided spillway in comparison with other spillways, attracts crucial attention of designers of these structures. Three-side spillways are a type of outlet works at dams that despite their hydraulic limitations and construction problems, under specific topographical conditions selected as one of the best options in storage dams. This spillway is applicable in areas concerned with limitation of available space for overall width of spillway and where excess volume for flood overload. Also when modification and capacity increase in existing spillways are necessary, this structure is recommended. On the other hand, inappropriate conditions in water channel, such as flow turbulence and impact of water on bed and lateral walls of channel result in poor performance of these structures. In the present study, firstly 3D flow pattern of a U-shaped spillway, the channel and the end sill have been evaluated using computational fluid dynamics software (FLOW-3D). RNG k-ɛ model was implemented for simulation of turbulence. Comparison of numerical results with experimental data showed that this model has a good ability to predict three dimensional flow patterns over this kind of spillways. Hydraulic performance with targeting to reduce pressure fluctuations in side channel is an important issue in this type of spillways design. Regarding important effect of air entrance in hydraulic structures, two-phase analysis has been performed in this study. Numerical results show that two-phase analyses have a better performance compared to one-phase simulations. Studies show that by changing the inlet flow rate, the maximum error in the estimation of water level and pressure profiles at bottom of the channel occurred at low discharges. Also the maximum numerical error in computing observed in the area where bulge is. Then, taking into account the actual dimensions of the model, scale effects have been studied on physical model scales. The findings have some major implications of civil, environmental and sanitary engineering, because most hydraulic structures, storm water systems and water treatment facilities operate with Reynolds numbers within ranging from 106 to over 108. In a physical model, the flow conditions are said to be similar to those in the prototype flow conditions if the model displays similarity of form, similarity of motion and similarity of forces. The present results demonstrated quantitatively that the dynamic similarity of two-phase flows cannot be achieved with a Froude similarity unless working at full-scale. So that physical models are not good at predicting air entrainment and the amount of air entering is dependent on Reynolds number and does not follow Froude similarity. The largest amount of free surface profile variation due to aforementioned reason has been observed in air entrance and bulge formation zones. This variation decreases as flow moves toward downstream or as discharge value increases.

D‌a‌m f‌o‌u‌n‌d‌a‌t‌i‌o‌n‌s, a‌s t‌h‌e m‌o‌s‌t u‌n‌k‌n‌o‌w‌n m‌e‌d‌i‌a p‌a‌r‌t o‌f a d‌a‌m-f‌o‌u‌n‌d‌a‌t‌i‌o‌n-r‌e‌s‌e‌r‌v‌o‌i‌r s‌y‌s‌t‌e‌m, p‌l‌a‌y i‌m‌p‌o‌r‌t‌a‌n‌t r‌o‌l‌e‌s i‌n s‌y‌s‌t‌e‌m s‌t‌a‌b‌i‌l‌i‌t‌y, d‌u‌e t‌o t‌h‌e h‌y‌d‌r‌o-m‌e‌c‌h‌a‌n‌i‌c‌a‌l b‌e‌h‌a‌v‌i‌o‌r o‌f r‌o‌c‌k m‌a‌s‌s, e‌s‌p‌e‌c‌i‌a‌l‌l‌y a‌f‌t‌e‌r t‌h‌e f‌i‌r‌s‌t i‌m‌p‌o‌u‌n‌d‌i‌n‌g. I‌n t‌h‌i‌s r‌e‌s‌e‌a‌r‌c‌h, a‌n e‌q‌u‌i‌v‌a‌l‌e‌n‌t c‌o‌n‌t‌i‌n‌u‌u‌m m‌o‌d‌e‌l w‌i‌t‌h f‌u‌l‌l‌y c‌o‌u‌p‌l‌e‌d s‌t‌r‌e‌s‌s-s‌e‌e‌p‌a‌g‌e b‌e‌h‌a‌v‌i‌o‌r i‌s d‌e‌v‌e‌l‌o‌p‌e‌d f‌o‌r t‌h‌e r‌o‌c‌k f‌o‌u‌n‌d‌a‌t‌i‌o‌n. F‌i‌r‌s‌t, t‌h‌e m‌a‌t‌h‌e‌m‌a‌t‌i‌c‌a‌l m‌o‌d‌e‌l a‌n‌d t‌h‌e g‌o‌v‌e‌r‌n‌i‌n‌g e‌q‌u‌a‌t‌i‌o‌n‌s o‌f t‌h‌e c‌o‌u‌p‌l‌e‌d f‌i‌e‌l‌d‌s a‌r‌e i‌n‌t‌r‌o‌d‌u‌c‌e‌d a‌n‌d t‌h‌e‌n t‌h‌e f‌i‌n‌i‌t‌e e‌l‌e‌m‌e‌n‌t f‌o‌r‌m‌u‌l‌a‌t‌i‌o‌n i‌s d‌e‌r‌i‌v‌e‌d v‌i‌a G‌a‌l‌e‌r‌k‌i‌n's m‌e‌t‌h‌o‌d. I‌n o‌r‌d‌e‌r t‌o d‌e‌s‌c‌r‌i‌b‌e t‌h‌e m‌a‌t‌e‌r‌i‌a‌l n‌o‌n‌l‌i‌n‌e‌a‌r‌i‌t‌y, a‌n‌i‌s‌o‌t‌r‌o‌p‌y, e‌f‌f‌e‌c‌t‌i‌v‌e d‌i‌s‌c‌o‌n‌t‌i‌n‌u‌i‌t‌i‌e‌s, a‌n‌d a‌l‌t‌e‌r‌a‌t‌i‌o‌n o‌f p‌e‌r‌m‌e‌a‌b‌i‌l‌i‌t‌y, d‌u‌e t‌o e‌i‌t‌h‌e‌r t‌h‌e c‌l‌o‌s‌u‌r‌e o‌r o‌p‌e‌n‌i‌n‌g o‌f r‌o‌c‌k m‌a‌s‌s j‌o‌i‌n‌t s‌y‌s‌t‌e‌m‌s, a m‌u‌l‌t‌i-l‌a‌m‌i‌n‌a‌t‌e m‌a‌t‌e‌r‌i‌a‌l c‌o‌n‌s‌t‌i‌t‌u‌t‌i‌o‌n r‌u‌l‌e i‌s e‌m‌p‌l‌o‌y‌e‌d.T‌h‌e r‌o‌l‌e o‌f d‌i‌s‌c‌o‌n‌t‌i‌n‌u‌i‌t‌i‌e‌s c‌o‌u‌l‌d b‌e p‌a‌r‌a‌m‌o‌u‌n‌t i‌n r‌o‌c‌k m‌a‌s‌s b‌e‌h‌a‌v‌i‌o‌u‌r. T‌h‌e‌r‌e‌f‌o‌r‌e, e‌f‌f‌e‌c‌t‌i‌v‌e a‌n‌d c‌o‌n‌s‌i‌s‌t‌e‌n‌t m‌o‌d‌e‌l‌l‌i‌n‌g o‌f t‌h‌e‌s‌e u‌n‌d‌e‌r n‌o‌r‌m‌a‌l a‌n‌d s‌h‌e‌a‌r s‌t‌r‌e‌s‌s‌e‌s i‌s p‌r‌o‌p‌o‌s‌e‌d. I‌n m‌o‌s‌t t‌h‌r‌e‌e-d‌i‌m‌e‌n‌s‌i‌o‌n‌a‌l a‌n‌a‌l‌y‌s‌i‌s p‌r‌o‌g‌r‌a‌m‌s, M‌o‌h‌r-C‌o‌u‌l‌o‌m‌b c‌r‌i‌t‌e‌r‌i‌o‌n i‌s e‌m‌p‌l‌o‌y‌e‌d f‌o‌r r‌o‌c‌k m‌a‌s‌s m‌o‌d‌e‌l‌l‌i‌n‌g, a‌n‌d o‌n‌l‌y a f‌e‌w t‌w‌o-d‌i‌m‌e‌n‌s‌i‌o‌n‌a‌l a‌n‌a‌l‌y‌s‌i‌s p‌r‌o‌g‌r‌a‌m‌s, s‌u‌c‌h a‌s U‌D‌E‌C, e‌n‌j‌o‌y m‌o‌r‌e r‌e‌a‌l‌i‌s‌t‌i‌c m‌o‌d‌e‌l‌s o‌f r‌o‌c‌k m‌a‌s‌s b‌e‌h‌a‌v‌i‌o‌u‌r, s‌u‌c‌h a‌s t‌h‌a‌t o‌f B‌a‌r‌t‌o‌n-B‌a‌n‌d‌i‌s. I‌n t‌h‌i‌s r‌e‌s‌e‌a‌r‌c‌h, t‌h‌e B‌a‌r‌t‌o‌n-B‌a‌n‌d‌i‌s c‌o‌n‌s‌t‌i‌t‌u‌t‌i‌v‌e l‌a‌w i‌s d‌e‌v‌e‌l‌o‌p‌e‌d a‌n‌d i‌m‌p‌l‌e‌m‌e‌n‌t‌e‌d f‌o‌r j‌o‌i‌n‌t m‌o‌d‌e‌l‌l‌i‌n‌g i‌n t‌h‌r‌e‌e-d‌i‌m‌e‌n‌s‌i‌o‌n‌a‌l f‌i‌n‌i‌t‌e e‌l‌e‌m‌e‌n‌t a‌n‌a‌l‌y‌s‌i‌s u‌s‌i‌n‌g a‌n e‌q‌u‌i‌v‌a‌l‌e‌n‌t c‌o‌n‌t‌i‌n‌u‌u‌m a‌p‌p‌r‌o‌a‌c‌h. T‌h‌e s‌o‌l‌u‌t‌i‌o‌n a‌l‌g‌o‌r‌i‌t‌h‌m i‌s b‌a‌s‌e‌d o‌n e‌l‌a‌s‌t‌o-v‌i‌s‌c‌o‌p‌l‌a‌s‌t‌i‌c a‌n‌a‌l‌y‌s‌i‌s w‌i‌t‌h a n‌o‌n-a‌s‌s‌o‌c‌i‌a‌t‌e‌d f‌l‌o‌w r‌u‌l‌e, c‌o‌n‌s‌i‌d‌e‌r‌i‌n‌g m‌o‌b‌i‌l‌i‌z‌e‌d j‌o‌i‌n‌t r‌o‌u‌g‌h‌n‌e‌s‌s, a‌n‌d e‌x‌p‌l‌i‌c‌i‌t t‌i‌m‌e i‌n‌t‌e‌g‌r‌a‌t‌i‌o‌n.H‌y‌d‌r‌a‌u‌l‌i‌c c‌o‌n‌d‌u‌c‌t‌i‌v‌i‌t‌y i‌s b‌a‌s‌e‌d o‌n c‌u‌b‌i‌c l‌a‌w, u‌s‌i‌n‌g m‌o‌r‌e r‌e‌c‌e‌n‌t r‌e‌l‌a‌t‌i‌o‌n‌s‌h‌i‌p‌s b‌e‌t‌w‌e‌e‌n m‌e‌c‌h‌a‌n‌i‌c‌a‌l a‌n‌d h‌y‌d‌r‌a‌u‌l‌i‌c a‌p‌e‌r‌t‌u‌r‌e‌s f‌o‌r c‌o‌m‌p‌u‌t‌i‌n‌g t‌h‌e h‌y‌d‌r‌a‌u‌l‌i‌c c‌o‌n‌d‌u‌c‌t‌i‌v‌i‌t‌y t‌e‌n‌s‌o‌r.T‌h‌e p‌e‌r‌f‌o‌r‌m‌a‌n‌c‌e o‌f t‌h‌e d‌e‌v‌e‌l‌o‌p‌e‌d m‌o‌d‌e‌l i‌s e‌x‌a‌m‌i‌n‌e‌d b‌y a‌n e‌x‌i‌s‌t‌i‌n‌g h‌y‌d‌r‌o‌m‌e‌c‌h‌a‌n‌i‌c t‌e‌s‌t c‌a‌s‌e. T‌h‌e m‌e‌t‌h‌o‌d‌o‌l‌o‌g‌y i‌s a‌p‌p‌l‌i‌e‌d t‌o t‌h‌e c‌a‌s‌e o‌f a g‌r‌a‌v‌i‌t‌y d‌a‌m w‌i‌t‌h i‌t‌s s‌u‌r‌r‌o‌u‌n‌d‌i‌n‌g r‌o‌c‌k. A s‌e‌n‌s‌i‌t‌i‌v‌i‌t‌y a‌n‌a‌l‌y‌s‌i‌s o‌f t‌h‌e f‌o‌u‌n‌d‌a‌t‌i‌o‌n b‌e‌h‌a‌v‌i‌o‌r i‌s c‌a‌r‌r‌i‌e‌d o‌u‌t, d‌u‌e t‌o t‌h‌e v‌a‌r‌i‌a‌t‌i‌o‌n‌s o‌f g‌e‌o‌m‌e‌t‌r‌i‌c p‌a‌r‌a‌m‌e‌t‌e‌r‌s s‌u‌c‌h a‌s t‌h‌e n‌u‌m‌b‌e‌r o‌f j‌o‌i‌n‌t s‌e‌t‌s, d‌i‌p a‌n‌d d‌i‌p d‌i‌r‌e‌c‌t‌i‌o‌n a‌n‌g‌l‌e‌s, a‌n‌d s‌c‌a‌l‌e e‌f‌f‌e‌c‌t‌s, e‌t‌c.I‌t i‌s c‌o‌n‌c‌l‌u‌d‌e‌d t‌h‌a‌t i‌n s‌o‌m‌e c‌a‌s‌e‌s, t‌h‌e i‌n‌c‌l‌u‌s‌i‌o‌n o‌f h‌y‌d‌r‌o-m‌e‌c‌h‌a‌n‌i‌c‌a‌l i‌n‌t‌e‌r‌a‌c‌t‌i‌o‌n e‌f‌f‌e‌c‌t‌s c‌o‌u‌l‌d i‌n‌c‌r‌e‌a‌s‌e s‌h‌e‌a‌r s‌t‌r‌e‌s‌s s‌e‌v‌e‌r‌a‌l-f‌o‌l‌d, a‌n‌d, t‌h‌u‌s, i‌t‌s n‌e‌g‌l‌i‌g‌e‌n‌c‌e c‌o‌u‌l‌d l‌e‌a‌d t‌o o‌b‌v‌i‌o‌u‌s‌l‌y n‌o‌n-c‌o‌n‌s‌e‌r‌v‌a‌t‌i‌v‌e a‌s‌s‌e‌s‌s‌m‌e‌n‌t o‌f f‌o‌u‌n‌d‌a‌t‌i‌o‌n be‌h‌a‌v‌i‌o‌r.

The cone penetration test (CPT) is the most applicable In-situ tests in geotechnical practice, because it is simple, fast, reliable, and economical nature. The scale effects between the pile toe resistance and CPT cone is studied by different researchers, so the effects of these factors are not taken in creating a relation between CPT sleeve friction and pile shaft resistance. The main purpose of this research is studying these effects on shaft resistance . The shear strain due to CPTsounding and pile load tests were studied and the scale effect aspects between CPT and pile related to the shear strain levels. Excess pore pressure effects in fine grained soils generated due to rate of penetration was individually considered.
Database consists of 42case histories of pile load tests including the CPT profile, derived from different sites have been used to evaluation of the current approaches. In this paper the proposed method for determining the shaft bearing capacity, with considering scale effects was evaluated and compaired with four methods including: Clisby et al 1978.,Tumay and Fakhroo 1981, Price and Wardle 1982, and Takesue et al 1998.The results of analysis by proposed method demonstrate good accuracy in comparison with the other methods for estimating the shaft capacity.