Pile Of Plates Research Articles

Shaking Table Test of Dynamic Response of Near-fault Rock-embedded Pile Foundation Under Strong Seismic Action

Dynamic response characteristics of near-fault bridge pile foundations under seismic wave action are studied by using a large shaking table model test. The results show that the peak acceleration at the top of the pile is more significant than that at the bottom. The pile top acceleration response is most significant for the EI-Centro wave and least significant for the 5002 wave. The maximum values of the permanent horizontal displacement of the pile top and the permanent relative horizontal displacement between the pile tops of the upper and lower plate piles appear under the action of the Kobe wave. The maximum pile bending moment appears to be at the interface of the upper overburden layer and the interface of the lower bedrock and overburden layer. The amplification coefficient of the pile top acceleration, the peak horizontal displacement of the pile top and the peak bending moment of the pile body of the upper plate pile foundation are more significant than those of the lower plate.

Influence of Plate Position on Uplift Failure State and Bearing Capacity of NT-CEP Pile Groups

The previous research results of the research group demonstrated that the plate position is the main factor affecting the uplift bearing capacity of the new type of concrete expanded plate pile (NT-CEP pile) group and the failure state of the soil around the pile. In this study, the visual half-section pile small-scale model of undisturbed soil tension test and ANSYS Finite Element Software comparative analysis two-pile small-scale test model and two-, four-, six-, and nine-pile models, which included the corner, side, and middle piles, were developed. The effect of the plate position on the displacement, stress, and bearing mechanism of the NT-CEP pile group under vertical tension was determined, which further improved the design concept of the NT-CEP pile group and provided strong theoretical support for its widespread application.

Study on safe crossing in the dry season and an anti-floating drainage scheme in the wet season: a case study in Guiyang, Southwest China

Karst formations in Southwest China are significantly developed. With the increase in tunnel construction year by year, constructing tunnels in areas of karst geology is inevitable. There are great safety risks associated with exposed karst caves, and the water inside the caves can seriously impact the tunnel structure and its filling materials. Traditional cave disposal technology mainly focuses on safe crossing treatment at the construction stage; however, problems such as backfill collapse and floor floating caused by karst water erosion during the service period are not considered. Therefore, proposals for a new construction scheme to ensure the stability and safety of the tunnel during the service period are urgently needed. Using Huangchongyan Tunnel as an example, we propose a safe crossing scheme of ‘plate–pile–bedrock’ for karst caves, based on a comparison of karst cave treatment schemes at home and abroad. In addition, considering the impact of karst water on the tunnel, we developed a ‘bottom to top’ reverse drainage structure, which solved the problem of floating during tunnel service. In our study, we developed a full life cycle disposal scheme to enable safe passage through tunnels in karst caves, providing a reference for the design and construction of similar projects.

Matched impedance amplifier design for shear-force acoustic near-field microscopy

Efficient detection of the acoustic signal constitutes the most critical aspect in Shear-force Acoustic Near-field Microscopy, for reliably characterize the dynamic response of confined fluids under shear stress. The near-field acoustic emission from the fluid is monitored as the probe gradually approaches to, and subsequently retracts from, the substrate. Herein we report a 7dB improvement in signal-to-noise sensitivity in detecting the acoustic emission from the fluid trapped between a flat sample and the apex of a tapered probe (the latter attached to a quartz tuning fork of 32 kHz resonance frequency). The new design capitalizes on the inherent capacitance of the SANM acoustic sensor (comprising a pile of piezoelectric plates) and a proper matching inductor/capacitance combination to, altogether connected in a tank-circuit fashion, optimize the sensor’s response at 32 kHz. A detailed construction of the circuit amplifier, as well as detailed frequency response bandwidth and noise characterization, is included herein.

Bearing characteristics of model piled raft foundations supported by sheet piles

Recently, with the development of new piling methods, steel sheet piles can be penetrated into various types of ground with high quality and precision. Although pipe piles are used for piled raft foundations, sheet piles could become an alternative. Thus, the aim of this research study is to demonstrate the possibility of using sheet piles for piled raft foundations. In this study, a series of model tests was carried out first to investigate the load transfer behaviours of model piled raft foundations supported by three types of piles in an air-dried sand ground. Two of them were composed of sheet piles, called plate piles and box piles, respectively, and the other was composed of conventional pipe piles for comparison. Both vertical and horizontal load tests were carried out, and the load sharing between the raft and piles was carefully investigated. As the plate pile foundation (PPF) exhibited outstanding behaviours, numerical analyses were carried out using finite-element methods to investigate the foundation–soil interaction in PPFs. According to test and calculated results, a piled raft foundation supported by sheet piles would be a promising alternative to a conventional pipe pile foundation, especially in highly seismic areas.

Photometric properties of piles of glass plates: retrospective.

Stacked glass plates have discreetly accompanied the understanding of light since the origins of modern optics. They were studied by Bouguer, Lambert, Brewster, Arago, Stokes, Rayleigh, and many others, whose successive works progressively refined the predictive formulas of the reflectance and transmittance of piles of glass plates as a function of the number of plates and the angle of incidence by considering the decay of light flux by absorption, the multiple reflections between plates, the change in the degrees of polarization, and the possible interferential effects. Through this history of ideas about the optical properties of piles of glass plates, up to the mathematical formalisms from only a few years ago, we show that these successive works, and their subsequent errors and corrections, are inseparable from the evolution of the quality of the glass available each time, in particular its absorptance and its transparency, which strongly influence the quantities and the degree of polarization of the reflected and transmitted beams.

Dynamic behavior of pile-supported wharves by slope failure during earthquake via centrifuge tests

The effects of earthquakes on pile-supported wharves include damage to piles by inertial forces acting on the superstructure, and damage caused by horizontal displacement of retaining walls. Piles can also be damaged through kinematic forces generated by slope failure. Such forces are significant but it is difficult to clearly explain pile damage during slope failure since the inertial force of superstructure and the kinematic force by slope failure can occur simultaneously during an earthquake. In this study, dynamic centrifuge model tests were performed to evaluate the effect of the kinematic force of the ground due to slope failure during earthquake on the behavior of a pile-supported wharf structure. Experimental results indicate that the slope failure in the inclined-ground model caused the deck plate acceleration and pile moment to be up to 24% and 31% respectively greater than those in the horizontal-ground model due to the kinematic force of the ground.

A striking example of ‘pile of plates’ altocumulus lenticularis near Marseille

WeatherVolume 76, Issue 1 p. E1-E1 Inside Cover Photograph A striking example of ‘pile of plates’ altocumulus lenticularis near Marseille First published: 13 January 2021 https://doi.org/10.1002/wea.3907Read the full textAboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onFacebookTwitterLinkedInRedditWechat No abstract is available for this article. Volume76, Issue1January 2021Pages E1-E1 RelatedInformation

Calculation Model of Bearing Capacity of the Rigid-Body Expanded Plate Pile under Horizontal Force in Ocean Engineering

Qian, Y.; Ai, S.; Wang, R., and Jin, Y., 2020. Calculation model of bearing capacity of the rigid-body expanded plate pile under horizontal force in ocean engineering. In: Liu, X. and Zhao, L. (eds.), Today's Modern Coastal Society: Technical and Sociological Aspects of Coastal Research. Journal of Coastal Research, Special Issue No. 111, pp. 345–351. Coconut Creek (Florida), ISSN 0749-0208.In ocean engineering, the pile foundation requires higher anti-overturning bearing capacity. The concrete expanded plate pile is the new type pile with advantages of energy saving, so it is applied widely in ocean engineering. By establishing the soil model of the expanded plate pile with different diameters, the displacement and load results of the expanded plate pile and soil are compared and analyzed, combining with the results of software simulation analysis and test to determine the failure state of soil around the rigid-body expanded plate pile under horizontal force. This paper proposes that the calculation model of the ultimate horizontal bearing capacity of the rigid-body expanded plate pile with soil failure be taken into consideration, which provides a theoretical basis for improving the calculation model of the horizontal bearing capacity of the rigid-body expanded plate pile.

Experimental Study on Effect of Plate and Plate End Forms on Pull-out Failure of Concrete Expanded Plate Pile Applied in Ocean Engineering

Qian, Y.; Zhang, J.; Wang, R., and Tian, W., 2020. Experimental study on effect of plate and plate end forms on pull-out failure of concrete expanded plate pile applied in ocean engineering. In: Liu, X. and Zhao, L. (eds.), Today's Modern Coastal Society: Technical and Sociological Aspects of Coastal Research. Journal of Coastal Research, Special Issue No. 111, pp. 93–100. Coconut Creek (Florida), ISSN 0749-0208.In ocean engineering, the most commonly used type of foundation is the pile foundation, which requires a higher pull-out bearing capacity. The concrete expanded plate pile is the new pile type, with advantages of energy savings and environmental protection and superior pull-out bearing capacity. Therefore, pile foundations are used widely in ocean engineering. Owing to differences in construction tools, the cross-section forms of the expanded plate and the concrete expanded plate pile will be different, which will also affect the failure state of soil mass around piles and plates. This study innovatively adopts the small-scale model tests of undisturbed soil of semisection piles to study the changes in the failure state of the soil mass around the pile due to the cross-sectional forms of the expanded plate with different bearing capacity under the action of vertical tensile force, and conducts a comparative analysis using ANSYS finite element simulation to determine the influence of the change of the plate cross-sections on the pull-out capacity of the concrete expanded plate pile.

Influence of Surface Structure, Pigmentation and Particulate Matter on Plant Reflectance and Fluorescence.

Optical properties of plant leaves are relevant to evaluate their physiological state and stress effect. The main objective of this work was to study how variegation, pigment composition or reflective features modifies leaves' photophysical behavior. For this purpose, green leaves (Ficus benjamina), purple leaves (Tradescantia pallida), green leaves covered by white trichomes (Cineraria maritima) and variegated leaves (Codiaeum aucubifolium) were analyzed. Firstly, foliar surface morphology was evaluated by scanning electron microscopy. UV-vis and near-IR reflectance and transmittance spectra were obtained to calculate absorption (k) and scattering (s) coefficients. The theoretical approaches of Pile of Plates and Kubelka-Munk's theory resulted still valid for nonstandard leaves with differing surface conditions. However, frequently used spectral indices were not reliable for predicting water content, when leaves differed from conventional ones. The proportionality between the absorption factor and chromophore/pigment concentration was also lost for hairy leaves. A simplified model to describe these facts was presented here. Fluorescence spectra were recorded and corrected, due to light re-absorption. Water-optical parameter connection and pigment-optical parameter connection were thoroughly discussed. Leaf surface morphology and pigmentation have not only influenced the optical features of leaves but also played a role in the effect that particulate matter could cause on leaf photosynthesis.

Elimination of Uneven Settlements During the Construction of Buildings in Complex Hydrogeological Conditions

The main factors influencing the occurrence of uneven settlement of buildings and structures are given. Since the existing methods of calculation of bases and foundations are not sufficient to ensure the guaranteed stability of buildings built on weak clay water-saturated soils, when designing it is necessary to assess the possibility of uneven settlements and provide ways to eliminate them at minimal cost. Based on the analysis of previously performed work on this issue and the conducted research, the designs of the foundation plate and the plate pile grillage are proposed, which make it possible to produce additional pressing or indentation of composite piles through holes in the plate when occurring a roll. The method of pressing composite piles using a support frame is described and the main measures that need to be carried out during the production of works are formulated. The use of the proposed method will reduce the cost of straightening the rolls by an order of magnitude and virtually eliminate the performance of these works at the stage of operation of the building.

IBEM-FEM model of a piled plate within a transversely isotropic half-space

This paper presents a numerical model of the vertical time-harmonic response of a piled-raft foundation under external and seismic excitations. The surface raft is a circular, rigid plate on the surface of the soil, while the pile is represented by a classical finite element bar model embedded within the soil. The soil is modeled as a homogeneous, transversely isotropic, viscoelastic half-space. The fully coupled response of the plate–pile–half-space system is modeled through a superposition of Green’s functions, in the framework of the indirect boundary element method. The article investigates the response of the coupled system for different sets of constitutive parameters, especially with regards to the effectiveness of the pile in reducing vibration amplitudes of the surface plate.

Perfect Transmission through Disordered Media.

The transmission of a wave through a randomly chosen "pile of plates" typically decreases exponentially with the number of plates, a phenomenon closely related to Anderson localization. In apparent contradiction, we construct disordered planar permittivity profiles which are complex valued (i.e., have reactive and dissipative properties) that appear to vary randomly with position, yet are one-way reflectionless for all angles of incidence and exhibit a transmission coefficient of unity. In addition to these complex-valued "random" planar permittivity profiles, we construct a family of real-valued, two-way reflectionless and perfectly transmitting disordered permittivity profiles that function only for a single angle of incidence and a narrow frequency range.

Uji Beban dan Analisis Lendutan Model Pelat Fleksibel yang Didukung Tiang-Tiang pada Tanah Pasir

Sand commonly has a good bearing capacity. Problems may occur when sand has low density and thick deposit. Flexible plate foundation may be used in this soil but plate deflection may be still high. To reduce deflection and improving soil density, piles were used to support the plate. Installing piles made foundation system stiffer. The objectives of this study are to studies about behavior of plates and plate with a pile of sand on the ground, influence of plate thickness , pile length and spacing of the pole deflection, and the influence of the bond between the plate and the deflection of the pile .In this study is used test box of 1.2 m depth, 1.2 m width, 1.2 m length, and 1.0 m depth filled out with sand. Plate models were made from plexiglas of rectangular and square geometry. Piles were of steel pipesof 2.5cm diameter. Some parameters were as follows : plate thickness, plate geometry, pile length (L), pile spacing (s), bounding between plate and pile (fix or free), ’piled’ and freestanding foundation, and base pile enlargement. The behavior of the plateswere observed under loading (point load). The result shows that plate deflections were affected by the method of pile installation, plate thickness and pile length. For a ticker plate, contact surface between plate and soil was wider. For the 40cmx10cm plates with fix end pile, deflectionswere founf to reduced up to 70% compared with free end pile. The ’piled foundation’ on 40cmx10cm plates, L=20cm, s=4d, deflections were reduced 83,63% compared with free standing foundation.

Numerical Simulation of Squeezed Branch and Plate Pile Subjected to Vertical and Lateral Loads

Based on the theoretical analysis results, the bearing behavior of squeezed and branch pile under vertical load and lateral load was analyzed in this paper. The mean works include the influence of vertical load on the pile lateral bearing capacity and influence of the lateral load on the vertical load bearing capacity. The factors influence the bearing capacity of pile such as elastic modulus of soil around and under pile bottom, pile length, plate position are also analyzed.

On the Circular Birefringence of Polycrystalline Polymers: Polylactide

The circular birefringence of polycrystalline polymers is invariably obscured by strong linear birefringence. To parse the two mechanisms of light retardation, polycrystalline spherulites of polylactide enantiomers were analyzed by Mueller matrix microscopy. Polymer films are barely optically active in normal incidence, but if illuminated obliquely they become strongly optically active. Opposite hemispheres have oppositely signed circular birefringence. The sign is independent of the enantiomer but dependent on the sense of the sample's tilt. These observations are consistent with light path inhomogeneities resulting from stacked, mis-oriented lamellae. Chiroptical commonalities based on symmetry arguments are discussed among polylactide, a single oriented water molecule, and microfabricated metamaterial arrays, as well as the first physical model of optical activity, Reusch's pile of mica plates. The latter model provides the best explanation of the circular birefringence of polylactide spherulites. The only data on the optical rotation of crystalline polymers to date come from ostensible single crystals of polylactide. The enormous, anisotropic optical rotations observed previously are in quantitative agreement with misoriented lamellae observed here. Limitations of parsing circularly birefringent systems into those showing 'natural optical activity' and those others, somehow 'unnatural', are discussed.

A probabilistic boundary element method applied to the pile dislocation problem

In this paper a probabilistic approach is presented where the boundary element method is efficiently used to study the effect of a random shift of a given pile within a particular pile cap from its original position–the so-called pile dislocation problem–on selected output design parameters such as pile loads and bending moments in the pile cap. A new circular internal element is developed to simulate the true geometric modeling of piles. The boundary element method for the shear-deformable (thick) plate theory is employed to analyze the pile cap. The plate–pile interaction forces are considered to have constant variation over the circular pile domain. The probabilistic approach presented herein incorporates a Monte Carlo simulation technique for generating random shifts in the original position of a given pre-selected pile. The procedure has been applied to some exemplar pile caps with given pile layouts typically adopted in bridge construction. The results demonstrate that the random dislocation of piles within practical ranges/values as customarily encountered for example in pile caps pertinent to bridge applications will cause limited variations in the output design parameters investigated herein and mentioned above. In other words, it has been illustrated that the resulting dispersion in the output values due to random dislocation of piles is less than the possible intrinsic dispersion that may be practically triggered in the pile locations due to common construction inaccuracies and/or unanticipated problems during pile driving process. The study further emphasizes the efficiency and reliability of the Boundary Elements Method adopted herein for such application.

Load Bearing Capacity Analysis of Squeezed Branch and Plate Pile under Vertical and Lateral Loads

Considering the initial stress field and concrete damage, no-linearity caused by crack of concrete, non-linear of reinforcement, elastic-plastic of soil around pile, couple interaction between concrete and steel, non-linearity contact of interface between pile and soil, the lateral load bearing capacity of squeezed branch and plate pile under vertical and lateral load is studied with infinite element and finite element couple method. The results indicate that the vertical load decreases the lateral displacement of pile top and increase the pile lateral load bearing capacity at the same time.

Fluorescence Polarization/Anisotropy in Diagnostics and Imaging

Fluorescence polarization was first applied in biochemistry almost 6 decades ago, when Gregorio Weber described his studies on bovine serum albumin and ovalbumin conjugated with 1-dimethylaminonaphthalene-5-sulfonyl chloride (dansyl chloride)1,2 (Figure 1). (For an overview of Gregorio Weber's wide-ranging contributions to fluorescence see3). Polarization methods became increasingly popular during the decades following Weber's work. During the past few decades, however, the increase in the number and diversity of fluorescence polarization studies has been astonishing and the method is now extremely wide-spread in the clinical and biomedical fields. The virtual explosion of polarization studies, which began during the mid-1980's, was due to several factors, including the availability of commercial instruments equipped with polarizers, the commercial availability of a great many fluorescence probes (largely due to the company Molecular Probes – now part of Invitrogen) and, in the clinical chemistry area, the introduction of the TDx instrument (and associated reagents) by Abbott Laboratories. The reasons for the popularity of fluorescence polarization in clinical and high-throughput assays are manifold. Firstly, polarization assays are homogeneous, i.e., there is no necessity for separation of free and bound ligand (these type of assays are often referred to as “mix and measure” assays). Secondly, and one of the original motivations for the development of fluorescence-based assays, there is no need for radioisotopes. Thirdly, polarization assays are reproducible and facilely automated. In this review we shall briefly trace the history of the technique and discuss in detail both theoretical and practical aspects. We shall also present copious examples from the literature, which illustrate the scope of the method in areas such as ligand binding, immunoassays, high-throughput screening, and live cell imaging and hint at future directions and applications. Figure 1 Gregorio Weber in Hawaii – 1989. Photograph courtesy of Prof. David Jameson. 2.0 Historical Overview As mentioned above, fluorescence polarization is widely applied in diverse fields, especially in the life sciences. A rough survey using Pubmed reveals that publications on fluorescence polarization/anisotropy numbered around a dozen in the 1950's, less than 100 in the 1960s, several hundreds in the 1970s, more than two thousand in the 1980's, more than three thousand in the1990s and close to four thousand in the 2000s to date. Given this rising trend, one may be curious how it all got started. We shall thus present a brief history of fluorescence polarization. 2.1 Discovery of Polarization In 1808, Etienne-Louis Malus observed sunlight reflected from the windows of the Luxemburg Palace in Paris through an Iceland spar (Calcite) crystal that he rotated (Erasmus Bartholin had discovered the double refraction of light by Iceland spar in 1669). Malus discovered that the intensity of the reflected light varied as he rotated the crystal and coined the term “polarized” to describe this property of light. He published his findings in 1809 4. Malus also derived an expression for calculating the transmission of light as a function of the angle (θ) between two polarizers. This equation (Malus' Law) is now written as: I(θ) = I0 (cos2θ). Some years later, David Brewster studied the relationship between refractive index and angle of incidence on the polarization of the reflected light 5. He discovered that for normal glass and visible light, an incidence angle of ∼56 degrees resulted in total reflection of one plane of polarization – this angle is now known as Brewster's Angle. This discovery allowed Brewster to construct a polarizer composed of a “pile of plates” (interestingly, when one of the authors – DMJ – first joined Gregorio Weber's laboratory as a graduate student, Weber showed him the “pile of plates” polarizer that he had used in some of his initial studies). In 1828, William Nicol joined two crystals of Iceland spar, cut at an angle of 68°, using Canada balsam, which allowed a spatial separation between the orthogonally polarized components. Other important calcite polarizers developed around this time include: Glan-Foucault; Glan-Thompson; Glan-Taylor; Wollaston; and Rochon. Most modern spectrofluorimeters today use Glan-Taylor type calcite polarizers, which have an air-gap between the two calcite crystals allowing for transmission deep into the ultraviolet, and which makes them less susceptible to photodamage at higher irradiance levels. But the Henry Ford of polarizers was Edwin Herbert Land. In 1929 Edwin Land patented the sheet polarizer (the J-sheet), consisting of crystals of iodoquinine sulfate embedded in nitrocellulose film followed by alignment of the crystals by stretching, which led to dichroism. In 1937 he founded the Polaroid Company and in 1938 he invented the H-sheet which comprised polyvinyl alcohol sheets with embedded iodine. Land's invention made him quite rich and also allowed the use of inexpensive polarizers in diverse applications such as sunglasses and photography filters.