Solid Friction Research Articles

Measuring of Low Frequency Internal Friction in Solids

The principles and apparatus of measuring low frequency internal friction are described in this paper. The low frequency internal friction apparatus have been evidently improved in automation and functions since the Ke,s pendulum was invented in 1947. The degree of automation of the internal friction apparatus is elevated and the functions of the apparatus are increased/ strengthened. The resolution of internal friction is increased. The accuracy of strain and frequency is also enhanced. The scope of measuring parameters such as temperature, strain, frequency and so on is enlarged.

Negative velocity dependence of friction for poly(2-Acrylamido-2-methyl propanesulfonic acid) hydrogel sliding against a glass surface in the low-velocity region

The frictional behavior of poly(2-acrylamido-2-methylpropanesulfonic acid) (PAMPS) hydrogel sliding against a glass substrate in water over a wide sliding velocity (v) region has been investigated. The results showed that the frictional behavior of PAMPS gel conformed to a hydrodynamic lubrication mechanism only at relatively high sliding velocities. At low sliding velocities, a “negative” velocity dependence of friction was observed, which we believe not to be attributable to the experimental friction-measuring mode used. This wider and weak mixed region at low sliding velocities is in contrast to the extremely narrow mixed region in the case of solid friction with a lubricant. The area of the PAMPS hydrogel surface subject to shearing decreased with increasing sliding velocity, and this would seem to be responsible for the weakly negative dependence of friction on velocity. In addition, the friction was found to increase with increasing the compressive modulus (E) of the gels attributing to the shearing exerted on the gel surface, in which the shear stress increased with E. The hydration layer between the sliding surfaces also contributes to the friction and weakens the dependence of friction on E to some extent. © 2014 Wiley Periodicals, Inc. J. Polym. Sci., Part B: Polym. Phys. 2014, 52, 765–772

On improving solid friction factor modeling for fluidized dense-phase pneumatic conveying systems

This paper presents results from an ongoing investigation into the modeling of solid friction factor for fluidized dense-phase pneumatic transport of powders. In spite of having the potential of being an energy economic and a better maintenance free mode of pneumatic transport, reliable design of fluidized dense-phase pneumatic conveying systems is still a difficult task due to the highly turbulent and complex nature of the flow of fine powders under high concentrations, where is it difficult to model particle–wall–air interactions. Several popular/applicable models (developed by other researchers, including one of the co-author of this paper) were evaluated to predict the total pipeline pressure loss for the dense-phase pneumatic conveying of fly ash (median particle diameter: 30μm; particle density: 2300kg/m3; loose-poured bulk density: 700kg/m3) and ESP dust (median particle diameter: 7 μm; particle density: 3637kg/m3, loose-poured bulk density: 610kg/m3) under different diameter and length scale-up conditions (viz. 69mm I.D.×168m; 105mm I.D.×168m and 69mm I.D.×554m pipes). These models are based on solids loading ratio and Froude number). A comparison between the predicted pneumatic conveying characteristics (PCC) and the experimental results showed that the models resulted in significant inaccuracy, especially under scale-up conditions of a new modeling technique has been developed using air velocity and a volumetric loading ratio term by replacing solid loading ratio and Froude number. The volumetric loading ratio term intends to address the product volume occupancy inside the pipeline, which is believed to be a better representation of flow conditions compared to mass ratio. The derived models were examined for scale-up accuracy by predicting pressure drop for different diameter/lengths of pipelines. It is found that the models have generally provided improved predictions in the dense-phase region. Whereas the existing models predicted with relative errors varying between 10 and 127% (depending on product and pipeline conditions), the new developed model resulted in predictions within 24% accuracy for a wide range of scale-up conditions, which provides better reliability and a narrower range of predictions, more suitable for industrial scale up requirements. Future work would require a more fundamental approach to understand the solid friction phenomenon for further accurate modeling.

Frictional performance of silicon carbide under different lubrication conditions

Abstract The frictional performance of materials used in face seals is critical to the sealing performance. Silicon carbide is commonly used in hard rings because of its abrasion resistance, corrosion resistance, and thermal shock resistance. In this study, the frictional performance of silicon carbide, including graphite-added silicon carbide, under water and lubrication-absent conditions was studied by using a Falex-1506 tribotester and different working parameters. In addition, the morphology of the worn surfaces was observed using scanning electron microscopy and the damage was characterized to understand the tribological behavior of different silicon carbides. The results suggest that the friction coefficients decrease with increasing pressure under water lubrication conditions because of the water within the holes on the surface of the materials. The percentage of water lubrication increases, whereas the percentage of solid friction decreases when the pressure increases. Under dry contact conditions, the friction coefficients change negligibly with increasing pressure and graphite-added silicon carbide shows better frictional performance.

Амплитудно-зависимое внутреннее трение и генерация гармоник в средах с гистерезисной нелинейностью

Амплитудно-зависимое внутреннее трение и генерация гармоник в средах с гистерезисной нелинейностью

Weak-noise limit of a piecewise-smooth stochastic differential equation

We investigate the validity and accuracy of weak-noise (saddle-point or instanton) approximations for piecewise-smooth stochastic differential equations (SDEs), taking as an illustrative example a piecewise-constant SDE, which serves as a simple model of Brownian motion with solid friction. For this model, we show that the weak-noise approximation of the path integral correctly reproduces the known propagator of the SDE at lowest order in the noise power, as well as the main features of the exact propagator with higher-order corrections, provided the singularity of the path integral associated with the nonsmooth SDE is treated with some heuristics. We also show that, as in the case of smooth SDEs, the deterministic paths of the noiseless system correctly describe the behavior of the nonsmooth SDE in the low-noise limit. Finally, we consider a smooth regularization of the piecewise-constant SDE and study to what extent this regularization can rectify some of the problems encountered when dealing with discontinuous drifts and singularities in SDEs.

An overview on the recent advances in computational fluid dynamics simulation of spouted beds

AbstractSpouted beds are now widely applied in various physical operations and chemical reaction systems due to their unique structural and flow characteristics. Now there are growing interests to use computational fluid dynamics (CFD) to understand dense gas–solid two‐phase flows in spouted beds. Both Eulerian–Eulerian (two‐fluid model, TFM) and Eulerian–Lagrangian (discrete element method, DEM) approaches can be applied to the CFD modelling of spouted beds and spouted‐fluidised beds, and numerous verification studies have shown their reliabilities. This overview summarises the recent advances of the TFM and DEM approaches in the CFD modelling of spouted beds. The typical flow patterns of spouted beds can be well reproduced by both the TFM and the DEM approaches, and the simulated characteristic properties such as spout diameter, minimum spouting velocity and voidage profile are in good agreement with experimental data, indicating that CFD modelling based on the TFM and DEM approaches can serve as an important tool for predicting gas and solids behaviour in spouted beds. The TFM approach has been widely used in phenomenological studies that are mainly towards the understanding of the flow behaviour of the whole system. Although more computational capacity is required, the DEM approach offers a more natural way to simulate gas–solid flows, with each individual particle tracked in the simulation and can be applied readily for particle tracking, collision, mixing, circulation and mass transfer studies that are aimed at obtaining the profound particle‐scale understanding in fluid–solid multiple‐phase systems. However, each approach has its own limitations and defects. The complex nature of the TFM‐based simulation framework requires both proper descriptions of pseudo‐fluid properties like solid pressure, solid viscosity, solid friction stresses, etc. and suitable choice of drag models, and the boundary conditions also have effects on the simulation results. Moreover, the effects of these factors often interact with each other, which require even more subtle skills in conducting a simulation. In the DEM approach, the high computing source requirement limits its application of no more than several million particles. Furthermore, more insight investigation should be given to the acting mechanism of several forces on particles. One common challenge for these two approaches is to properly describe the inherent turbulence for both the solid and gas phases, especially for the spout region. Further fundamental and experimental studies on the kinematic properties of the two phases are needed to improve the accuracy of the CFD models.

A Study of Wind Heating System

At present, the world is facing energy shortage, while the CO2 emitted from the combustion of traditional energy causes greenhouse effect. As a result, the green concept of energy saving has emerged. Among the current green energies, solar power is not cost effective, and wind energy has great potential in terms of cost and efficiency. Most of wind energy is used for wind power generation, however, the wind energy is also applicable to heating, and the generated heat energy can be used for hot water supply and temperature regulation. The wind heating modes include fluid mixing and solid friction modes. This study used natural wind to design a machine producing heat energy by solid friction. The energy transfer mode of the wind heating system was to convert the blade extracted wind energy into mechanical energy, and use friction to generate mechanical energy generates. The heat energy was transferred to the water through heat exchange to increase the water temperature. The friction mode was to rub the brake pad against the disc to produce heat, and using the compression spring to adjust the magnitude of the friction. The pump circulated water to implement forced convection, and the heat exchange was designed as flowing water channel increasing the heat transfer time. The experimental results showed that the water storage temperature can be increased.

Modeling of a Chemical Looping Combustion Process in Interconnected Fluidized Beds with a Cu‐Based Oxygen Carrier

AbstractChemical looping combustion (CLC) is a promising technology for CO2 capture, with inherent CO2 separation and low energy consumption. In this study, the reactive multiphase model is incorporated into a computational fluid dynamics code to simulate the reactive fluid dynamics in the CLC reactor with a two‐fluid model. The solid friction stress is used to account for the interaction of individual particles with their neighbors through sustained contact at high particle concentrations and the kinetic theory of granular flow is used for closure. Gas‐solid flow characteristics and chemical reactions in interconnected fluidized beds using a Cu‐based oxygen carrier are simulated. The distributions of solid concentration and gas composition are obtained. The predicted gas compositions at the outlet agree with experimental results. The effects of the operating velocity and the temperature on the combustion efficiencies are also shown. The results demonstrate that a higher bed temperature at a lower operating velocity could enhance the CLC performance.

Novel intermittent solid slug feeder for fast pyrolysis reactors: Fundamentals and modeling

To prevent plugging and help the raw biomass particles effectively penetrate and spread into the pyrolysis fluidized beds, one could inject the particles using intermittent slugs created by propelling loosely packed particles with gas pulses and transporting them along horizontal or inclined feeding pipes into the fluidized bed section of the reactor; this would combine the advantages of the low gas consumption of the screw feeders and the short residence time in high temperature zones of dilute phase feeders.Dried distillers' grain (DDG) and meat and bone meal residues (MBM) were selected as model feedstocks for experimental testing and modeling of a novel intermittent solid slug feeder technology. These feedstocks were chosen as much work has been done to attempt to process them into value-added products via fast pyrolysis, but they also possess very challenging flow characteristics and properties that are very different from each other (particle size, cohesivity, temperature sensitivity, density). As a result, creating a predictive model that can successfully model these challenging feedstocks is the basis to model any biomass of interest.The biomass flow in the feeding tube begins as an induced dense-phase flow and develops into a high velocity ‘aerated bed flow’. Gas leakage, solid friction and force-momentum balances were considered in the model. The model was developed from experimental data collected with simplified plugs (modified nylon ball), as well as real biomass slug flow.Several important variables were identified. They included the material flow properties, the gas capacitance pulse pressure and volume, and the length and material of feeding tube. The goals of this study were to (a) characterize the fundamental dynamic behavior of the biomass slugs in the feeder, (b) maximize the solid-to-gas feeding ratio, and thus minimize energy consumption, (c) minimize the accumulation of “straggler” biomass material in the feeding tube between pulses, and thus preventing biomass pre-cooking in the feeding tube and plugging (d) develop and validate a predictive model for the slug velocity at any point in the feeding tube (and thus the maximum feeding tube length), that can be applied for feeder and reactor design for any biomass feedstock, and (e) identify future areas of work for the ICFAR intermittent solid feeder.

Investigating Straight-Pipe Pneumatic Conveying Characteristics for Fluidized Dense-Phase Pneumatic Conveying

This article presents results from an investigation into the pneumatic conveying characteristics (PCC) for horizontal straight-pipe sections for fluidized dense-phase pneumatic conveying of powders. Two fine powders (median particle diameter: 30 and 55 µm; particle density: 2300 and 1600 kg m−3; loose-poured bulk density: 700 and 620 kg m−3) were conveyed through 69 mm I.D. × 168 m, 69 mm I.D. × 148 m, 105 mm I.D. × 168 m and 69 mm I.D. × 554 m pipelines for a wide range of air and solids flow rates. Straight-pipe pneumatic conveying characteristics obtained from two sets of pressure tappings installed at two different locations in each pipeline have shown that the trends and relatively magnitudes of the pressure drops can be significantly different depending on product, pipeline diameter and length and location of tapping point in the pipeline (indicating a possible change in transport mechanism along the flow direction). The corresponding models for solids friction factor were also found to be different. There was no distinct pressure minimum curve (PMC) in any of the straight-pipe PCC, indicating a gradual change in flow transition (change in flow mechanism from dense to dilute phase). For total pipeline conveying characteristics, the shapes of the PCC curves and the location of the PMC were found to be significantly influenced by pipeline layout (e.g., location and number of bends) and not entirely by the dense-to-dilute-phase transition of flow mechanism. Seven existing models and a new empirically developed model for PMC for straight pipes have been evaluated against experimental data.

Modeling of Viscoelastic Cable-Conduit Actuation for MRI Compatible Systems

Cable transmission has significant advantages in the development of a surgical robot which is fully magnetic resonance imaging (MRI) compatible and can work dexterously in the very limited space inside MRI core. However, apart from the nonlinearities due to friction and cable compliance present in the traditional steel cables, the MRI compatible polymeric cables also suffer from the significant viscoelastic behavior. Previous work in cable-conduit actuation modeling only addresses the transmission in elastic cables and ignores complex direction and time dependent nonlinear viscoelastic behavior of cable-conduits. These effects need to be characterized for system design and nonlinearity compensation. In this paper, an analytical model using standard linear solid model and Coulomb friction is developed to study the transmission characteristics of such a system. The model has been validated by experiments using dyneema cables passing through PEEK conduits, predicting motion and torque transmission with error levels of 3.38% and 16.16%, respectively. The effect of cable viscoelasticity is studied utilizing the model, and corresponding results are compared with that of an elastic cable.

LES–DEM investigation of an internally circulating fluidized bed: Effects of gas and solid properties

Gas–solid flow dynamics of a three-dimensional baffle-type internally circulating fluidized bed (ICFB) is numerically investigated in this paper. Detailed multiphase flow characteristics are illustrated using a computational fluid dynamics–discrete element method (CFD–DEM) in which the gas flow field is modeled using large eddy simulation (LES) while solid kinematics is handled by soft-sphere model. The mechanisms of the internal circulation are addressed together with instantaneous and time-averaged results and solid rotation plays an important role as that of its translational motion. Simulations are also carried out to examine the influences of gas–solid properties (bed pressure, solid friction coefficient, restitution coefficient, Young modulus, diameter and density) on the bed circulation performance, which is quantified by the solid circulation flux (SCF) and gas bypassing flux (GBF). The results indicate that the behaviors of solid circulation and the corresponding gas bypassing exhibit great resemblance, especially when the solid properties change. The gas property, bed pressure, seems to show significant influence on the gas bypassing flux. Meanwhile, both solid circulation and gas bypassing are affected by the solid properties to a larger extent. They are enhanced with increasing solid density, restitution coefficient and gas pressure, while weaken as the solid friction coefficient, diameter and gas temperature increases. However, solid Young modulus shows inconspicuous influence on the circulation performances of the bed. Furthermore, additional normalization of the simulation data finds that the minimum fluidization velocity (Umf) of the system is a key parameter to the operational control of the ICFB.

The Friction Welding Characteristic Analysis of the Al 7075-T6 According to the Spindle Speed and Upset Pressure

The propeller shaft of rear-wheel drive vehicle is an axis which transfers power from an engine to rear-wheel through differential gear box. In this study, we studied the properties of friction welding required to produce the aluminum propeller shaft of lightweight rear-wheel-drive vehicle. We studied welding property to apply Al 7075-T6 aluminum yoke to automobile connects driving shaft and differential gear box. Here, solid phase friction welding method was used. In friction welding process, the principal parameter is spindle speed, up-set pressure and up-set time. We analyzed variable characteristics of friction welding strength according to the change of the spindle rate and up-set pressure. Friction welding strength was analyzed with ultimate tensile strength test with universal testing machine (UTM). The Al 7075-T6 was used as the round bar of the diameter of 25mm. The ultimate tensile strength was 552.3 MPa. It is 94% of ultimate tensile strength of pure Al 7075-T6 material. The main parameters of characteristics are discussed in detail based on analysis of the main effects plot and multi-vari chart. Finally, the core factors to get the maximum effect of friction welding investigated.

Numerical-analytical investigation into impact pipe driving in soil with dry friction. Part II: Deformable external medium

Under analysis is travel of P-waves in an elastic pipe partly embedded in soil with dry friction. The mathematical formulation of the problem on impact pipe driving in soil is based on the model of axial vibration of an elastic bar, considering lateral resistance described using the law of solid dry friction. The author solves problems on axial load on pipe in interaction with external elastic medium, and compares the analytical and numerical results obtained with and without accounting for the external medium deformability.

Pressure drop prediction for horizontal dense-phase pneumatic conveying of pulverized coal associated with feeding to gasifier

Based on extensive bench-scale data derived from the horizontal dense-phase pneumatic conveying of pulverized coal, a correlation of solids friction factor λz was proposed in an effort to establish a model to predict the pressure drop when coal fed to the gasifier. Further, it was also an attempt to modify some public models to verify their availabilities. Then, based on the data collected from an industrial-scale horizontal pipeline under the high pressure up to 2.0MPa, the proposed model was found to be possibly among the best ones for predicting the pressure drops of the dense flow of pulverized coal. The modified Mallick and Wypych model can also provide satisfying predictions. The results suggest that the two models are both suitable for scale-up of dense-phase pneumatic conveying of pulverized coal at high pressures.

Modeling and Analysis of Solids Friction Factor for Fluidized Dense Phase Pneumatic Conveying of Powders

Pressure drop in pneumatic conveying is due to frictional interaction among gas, particle, and pipe wall. Fictional forces due to solids can be calculated using a solids friction factor. Many correlations have been proposed for predicting solids friction factor in dilute phase pneumatic conveying. These correlations are calculated based on value of the parameters calculated for a long pipeline or value of the parameter at the inlet of the pipeline. Pneumatic conveying in long pipelines suggests that some of the flow parameters are not constant along the length of the pipeline. This article presents a modeling technique for predicting solid friction factor taking into account of the local value of flow parameter. In this method, the solids friction factor is presented in terms of coefficient and exponents. The values of coefficient and exponents are predicted for fluidized dense phase conveying using different types of conveying materials. Values of coefficient and exponents are found to be different for different types of conveying materials. Variations of different parameters are studied using the calculated optimum values of coefficient and exponents. Experimental data are also used to find the possible maximum conveying distance or pipe diameter by imposing certain limiting conditions of conveying.

Electrorheological behaviour under oscillatory shear of TiO2 rod-like particles prepared via microwave-assisted molten-salt synthesis

Titanium dioxide (TiO2) rod-like particles were synthesized by a simple and rapid microwave-assisted molten-salt method. The X-ray diffraction analysis and electron microscopy provided information on particle composition and morphology, respectively. It was found that during the synthesis process the crystalline phase of TiO2 transformed from anatase into rutile while the morphology changed from nanospheres into micrometer sized rod-like particles. The electrorheological (ER) properties were investigated via oscillatory shear tests. It was found that TiO2 rod-like particles based silicone oil suspensions exhibited higher ER activity than those of original anatase TiO2 nanoparticles probably due to side-by-side solid friction between particles as well as shorter time of their polarization. The changes in ER properties of rod-like particle based suspensions as a function of the applied electric field strength and particles weight fraction were also investigated.

Characterisation of friction reduction with tangential ultrasonic vibrations using a SDOF model

Active control of friction between sliding surfaces is of fundamental and practical interest in automotive applications. It has been shown that the friction force between sliding surfaces decreases when ultrasonic vibration is superimposed on the sliding motion. This principle can be applied to systems in which solid state lubrication or friction modulation is advantageous. The ultrasonic vibration may be applied longitudinally or normal to the direction of motion. A number of friction models have been considered in order to analyse this phenomenon. The degree of friction reduction has been shown to depend on the ratio of the sliding velocity to the vibration velocity. Since friction is a system response, it is necessary to include system dynamics in the analysis of ultrasonic lubrication. A nonlinear single-degree-offreedom-model is formulated and numerically approximated to quantify the effect on friction reduction of control force, intrinsic coefficient of friction, mass load, tangential contact stiffness at the sliding interface, and system stiffness. Model results are in close agreement with experimental measurements.

Parameter Sensitivity Analysis on Pressure Drop of Gas-solid Flow for Absorber Sphere Pneumatic Conveying

The pressure drop of gas-solid flow for absorber sphere pneumatic conveying is important for the design and operation of the gas circulator. The simplified one-dimension model is introduced to predict the pressure drop of gas- solid flow for absorber sphere pneumatic conveying. The pressure drop of gas-solid flow in the vertical pipe is the main component part of the total gas-solid flow for absorber sphere conveying. The pressure drop of gas-solid flow for absorber sphere conveying in the vertical pipe with the inside diameter 47mm and conveying height 23 m is predicted by the simplified model. The superficial gas velocity considered is in the range of 1.5 to 3.0 times of the terminal velocity of a single particle. The solid mass flow rate considered is in the range of 0.2 to 1.2kg/s. Particle velocity, solid friction factor and solid mass flow rate are important parameters to predict pressure drop of vertical pipe. The typical empirical correlations of particle velocity and solid friction factor reported in the literature are adopted to predict the pressure drop of vertical pipe. The superficial gas velocity for absorber sphere conveying is suggested to be two times of the terminal velocity of a single particle. For the suggested superficial gas velocity, the predicted pressure drop of vertical pipe by using empirical correlations is in the range of 15 to 20kPa and 31 to 50kPa for solid mass flow rate at 0.2kg/s and 1.2kg/s, respectively. For the suggested superficial gas velocity, the relatively conservative predicted pressure drop of vertical pipe is in the range of 20 to 78kPa for solid mass flow rate in the range of 0.2 to 1.2kg/s. Further work is needed to verify the pressure drop model and to modify the key parameters for absorber sphere conveying in helium.