Impact Of Velocity Research Articles

Experimental Study on the Surface Cutting Mechanical Properties of Single Crystal Silicon in Micro-Nano Scale

The experiment of cutting mechanical properties of single crystal silicon surface in the micro-nanoscale is researched using nanoindenter and atomic force microscopy. The result of the experiment shows that: in the constant load, the impact of different scratching velocity for single crystal silicon surface scratch groove width and chip accumulation volume are not big; but the cutting force and friction coefficient are not increases with the scratching velocity increases; when the scratching speed is certain, the size of load has a greater impact on the cutting mechanical properties of single crystal silicon surface, with the increase of the load, the cutting force increases, but the cutting force is not linearly growth.

Innovative Steam Drying of Empty Fruit Bunch with High Energy Efficiency

Empty fruit bunch (EFB) is one of the solid wastes from crude palm oil mills and has the lowest value for utilization compared to other solid wastes. To achieve an efficient utilization of EFB, drying is considered the first crucial process due to the high moisture content of EFB. In this study, EFB drying based on exergy recovery is proposed to achieve high energy efficiency. A fluidized bed is adopted as the main dryer. The proposed model is evaluated in terms of energy efficiency, especially regarding the influence of target moisture content and fluidization velocity. Up to 92% of the energy involved in the drying process can be recirculated. The total energy consumption for drying decreases as the target moisture content decreases, though there is no significant impact of fluidization velocity to total energy consumption. In addition, the required total length of the heat transfer tubes immersed inside the fluidized bed dryer is calculated because it relates to fluidization performance and economic issues. Lower target moisture content results in a longer heat transfer tube, and higher fluidization velocity leads to a shorter heat transfer tube.

PM2.5 removal performance of a wire-pipe ESP under multi-field coupling and applied magnetic field

In order to study PM2.5 removal performance under multi-field coupling and applied magnetic field, a mathematical model was proposed to analyze the interaction between fluid flow field, electro- magnetic field and particle dynamic field. The computational fluid dynamics method and FLUENT were employed to numerically simulate the PM2.5 removal performance in a Wire-pipe ESP. The effects of magnetic field on PM2.5 collection efficiency at different working voltages and gas velocities were discussed. The results indicate that the influence of applied magnetic field on PM2.5 collection in the wire-pipe ESP becomes more obvious with the increase of the particle diameter, and the increment of PM2.5 grade efficiency decreases with the increasing magnetic flux density in a certain range of particle diameters. Furthermore, the effect of magnetic field on PM2.5 collection increases with a decrease of working voltage or an increase of gas velocity, and PM2.5 collection efficiency declines at the same time. At a lower flue gas velocity, the impact of flue gas velocity on PM2.5 overall efficiency is more significant than that of applied magnetic field.

Experimental Study on the Effect of Road Rollers Construction Vibration

Rollers are widely used in the construction of infrastructure; the influence of vibratory on surrounding environment caused by roller in construction is increasingly prominent. In order to solve this problem, a monitoring experiment was conducted in a compacted subgrade construction site to show how the vibratory of roller impact on surrounding environmental. Through the analysis of compacted subgrade monitoring data show that the peak fast decline rapidly with distance attenuation, the prediction formula is: a = 1657.85 * R ^ (-1.1), Based on the impact of compacted subgrade vibration velocity, frequency, and duration on the surrounding buildings is analyzed and found that the vibration velocity and frequency are less impact on the housing, but the duration of the construction will have an impact. Lastly, from Z vibration level and seismic intensity angle, the effects of vibration on personal feelings and building structures caused by vibration acceleration is analyzed. Furthermore, the way of excavating vibration attenuation ditch to control effect of vibration is proposed to the greatest impact of vibration on the residential buildings.

Research on Foam-Separation Type of Surfactant Wastewater Treatment

Foam-separation wastewater treatment is conducted by the adsorption principle of surfactant. In this paper, we adopted CTAB simulated wastewater for separation study, taking removal rate and enrichment ratio as the evaluation index. It’s been studied about the impact of operating-parameter gas velocity, liquid volume and time on the effect of separation, and further the appropriate process parameter.

Research of Human Modeling and Motion Simulation Based on ADAMS

The human model in this paper is simplified as a rigid body of 15 segments and the Roberson-Wittenberg method is used to establish the equation of conservation of angular momentum to obtain the control methods of human self-rotation without external force in a weightless environment. And simulation of human dynamic is completed in ADMAS (Automatic Dynamic Analysis of mechanical Systems). The simulation results show that human can generate corresponding body rotation through own limbs rotation in the weightless, and body rotation velocity and angle increase with the moment of inertia and rotational velocity of active body that adds greater torque to joint. Through the analysis of the impact of the angular velocity and torque on the body rotation, a set of self-rotation control strategy for astronaut is proposed in weightless environment.

Hot Radial Upset-Extruding Process for Tube Structure with a Nozzle of 316LN Stainless Steel

AP1000 nuclear power main pipe, a type of complicated thick-walled tube structure with both high and thick-walled nozzles, is one of the key parts in nuclear island. It is required to be manufactured by integral plastic forming technique. Up to now, no economical and efficient plastic forming process for AP1000 main pipe has been reported. To aim for forming the tube structure with a nozzle such as AP1000 main pipe, a radial upset-extruding (RUE) process was developed, in which the initial billet is an extruded tube with a hole. RUE process is an extrusion method which realizes radial outflow of the metal around the hole of tube billet through an axial upsetting force and restriction of dies. Thick-walled tube structure with a nozzle derived from AP1000 main pipe was simplified to be a thick-walled three-way pipe, on which RUE process was analyzed based. Combined with reduced scale model experiments, thermomechanical coupled finite element analysis integrated with recrystallization models of 316LN was performed to investigate RUE process. Metal flow, deformation distribution, recrystallization distribution, and extrusion load and clamping load in RUE process was analyzed. The experimental workpiece of pure lead based on reduced scale model validate metal flow behavior predicted by using numerical simulation. The results indicate that the essence of RUE process is to deflect the flow of the material around the orifice of the tube billet. The loads of dies are significantly sensitive to the initial forming temperature and the friction coefficient, while the impact of the extrusion velocity is negligible. RUE process could be used to form thick-walled tube structure with a nozzle, and it has a potential for solving the manufacture of AP1000 main pipe.

Numerical Simulation of Tire Hydroplaning and its Influencing Factors

Tire hydroplaning has become a direct inducement of wet-weather road accidents. The model of hydroplaning of the deformed rib tire with load was built with the help of CFD (Computational Fluid Dynamics) technology. The three-dimensional SST coupled with the Volume of Fluid (VOF) model was applied to numerically simulate the air-water two phase flow with free surface in tire hydroplaning. Based on the model of hydroplaning, the influence of water film and water velocity on tire hydroplaning were analyzed. Analysis shows that tire has a high pressure induced by water impact in the front of footprint; water flow is inclined to tire sidewall. The water velocity in different circumferential pattern is difference. There is an apparent impact of water film thickness and velocity on tire hydrodynamic pressure and the high pressure zone. Therefore, the results of this paper can give recommendations on drivers in the rainy weather.

Modeling the Influence of Wind Velocity and Water Content on Coal Dusts in Wind Tunnel

Emission of coal dusts can cause serious air pollution in coal-pile storage yard, which poses a threat to human health. Therefore, the quantitative research on particulate emissions is the premise for dealing with atmospheric pollution. In this paper, a series of experiments are firstly carried out in wind tunnel to study the impact of the wind velocity and water content on coal dusts for the mixing pile. Moreover, particle entrainment is investigated by measuring the velocity required to pick up particles from rest, also known as threshold velocity. Then a number of experimental data are obtained and a fitting formula is derived with the aid of Matlab. Finally, the results are compared with those published previously, and explanations about the differences are given.

Study on Recovery of Metals from Printed Circuit Board Using a Gas-Liquid Fluidized Bed

Comminuting and enrichment are the key technology to recycle waste printed circuit boards (WPCBs), in this paper the mechanical separation of WPCBs, comminuting by bang comminute and enrichment by air-solid fluidized bed, was studied. Experiments were designed to examine the impact of the airflow velocity and particle diameter to the air separation process, in order to optimize the operation condition. The results illustrated that it is feasible and very effective to apply gas-solid fluidized bed to recycle WPCBs.

Correction for body displacement for accurate delivery of chest compressions on a soft surface: The triaxial field induction technology

Introduction:Wehave previously reported the benefit of faster release velocity on central blood flows in a porcine model of prolonged CPR without rescue shocks or vasopressor administration. We examined the importance of release velocity with vasopressor administration during the same model of prolonged CPR. Methods: CPR hemodynamics in four domestic swine were studied using standardmonitoring. Flowprobeswere placed on the inferior vena cava (IVC) and the right common carotid. Ventricular fibrillation (VF) was electrically induced. A mechanical chest compression (CC) device was started after ten minutes of untreated VF. CC release was changed so that sternal recoil lasted 100ms (WF1), 200ms (WF2), or 300ms (WF3). CC were delivered at a rate of 100 perminute and a depth of 48mm. Transitions between randomized waveforms occurred every 2min. Vasopressors were given every two minutes using the following pattern: epinephrine (1ml/kg), epinephrine (1ml/kg), vasopressin (40U/kg). Results: Throughout the first 18min of CC, aortic pressure was significantlyhigher and right atrial pressurewas significantly lower with WF1 and WF2 compared to WF3 (p<0.05). Carotid flow was higher with WF1 compared to WF3 (p<0.05). IVC flow was higher with WF1 in the first 8min of CC compared to WF3. Min 8 to 18 showed similar IVC flows for WF1 and WF2 which were higher than WF3 (p<0.05). During the first 18min of CC, IVC and carotid blood flows produced by WF3 with vasopressors were 3-fold less than those produced by WF3 in our no-vasopressor model. Conclusions: The use of vasopressors increased the impact of CC release velocity. The arterial-venous pressure difference, cerebral blood flow, and venous return were highest when the sternal recoil timewas 100ms. However, the use of vasopressors tended to decrease carotid and IVC flow and exacerbated the negative effect of slow release.

Increasing importance of release velocity with vasopressor use in a porcine model of cardiac arrest

Introduction:Wehave previously reported the benefit of faster release velocity on central blood flows in a porcine model of prolonged CPR without rescue shocks or vasopressor administration. We examined the importance of release velocity with vasopressor administration during the same model of prolonged CPR. Methods: CPR hemodynamics in four domestic swine were studied using standardmonitoring. Flowprobeswere placed on the inferior vena cava (IVC) and the right common carotid. Ventricular fibrillation (VF) was electrically induced. A mechanical chest compression (CC) device was started after ten minutes of untreated VF. CC release was changed so that sternal recoil lasted 100ms (WF1), 200ms (WF2), or 300ms (WF3). CC were delivered at a rate of 100 perminute and a depth of 48mm. Transitions between randomized waveforms occurred every 2min. Vasopressors were given every two minutes using the following pattern: epinephrine (1ml/kg), epinephrine (1ml/kg), vasopressin (40U/kg). Results: Throughout the first 18min of CC, aortic pressure was significantlyhigher and right atrial pressurewas significantly lower with WF1 and WF2 compared to WF3 (p<0.05). Carotid flow was higher with WF1 compared to WF3 (p<0.05). IVC flow was higher with WF1 in the first 8min of CC compared to WF3. Min 8 to 18 showed similar IVC flows for WF1 and WF2 which were higher than WF3 (p<0.05). During the first 18min of CC, IVC and carotid blood flows produced by WF3 with vasopressors were 3-fold less than those produced by WF3 in our no-vasopressor model. Conclusions: The use of vasopressors increased the impact of CC release velocity. The arterial-venous pressure difference, cerebral blood flow, and venous return were highest when the sternal recoil timewas 100ms. However, the use of vasopressors tended to decrease carotid and IVC flow and exacerbated the negative effect of slow release.

Cross-Flow Microfiltration of Bacillus Subtilis Broths under Various Culture Times

Bacillus subtilis broths under different culture times are filtered in a cross-flow microfilter. The operating condition effects, such as cross-flow velocity, transmembrane pressure, and broth culture time, on the filtration flux, cake properties, and extracellular polymeric substances (EPS) transmissions are discussed thoroughly. The culture broths contain B. subtilis cells and EPS which is characterized as polysaccharides (hydrocarbons) and proteins. An increase in broth culture time leads to higher concentrations of cells, soluble and extractable EPS. The total protein to polysaccharide concentration ratio in the broths is ca 0.2. However, the soluble polysaccharide concentration is 10-fold higher than that of soluble proteins. The filtration flux increases with increasing cross-flow velocity or transmembrane pressure. However, the impact of cross-flow velocity is more significant. The filter cake resistance formed by B. subtilis cells and EPS flocs plays the most important role in determining the overall filtration resistance. The mass and average specific filtration resistance of cake can be estimated using a force balance model and empirical equations. The cake structure and thickness are analyzed using SEM. A thicker and more compact cake may be formed under longer broth culture time. Most soluble polysaccharide and protein molecules have the opportunity to penetrate through the cake and membrane into the filtrate because the solute transmissions are measured as high as 0.75–1.0. The influences of operating conditions on the polysaccharide and protein transmissions are negligible. Therefore, to enhance filtration flux by increasing transmembrane pressure or cross-flow velocity is beneficial to improve separation efficiency, especially by increasing cross-flow velocity.

Evaluation of the impact of wheel tractor velocity and other factors on its oscillations

Vertical oscillations of tractor Т-150К during operation on sandy soddy-podzolic soil prepared to sowing were investigated. As result of calculations carried out using experimental data on viscoelastic soil properties, the influence of a tractor velocity on appearance of mutually independent oscillations of its axes was shown.

Three-Dimensional Simulations of Strong Ground Motion in the Shidian Basin

Seismic response of the Shidian basin to moderate scenario earthquake is investigated considering 3D basin model incorporated with real topography by using the spectral-element method and parallel computing technique. The wave propagation process, the generation of surface wave, and the impact of soil deposits velocity to the basin-induced surface wave are studied in this paper. The results show that the amplification behavior of the basin is the interactions of basin geometry and low velocity soil deposits. First, locally small hollows in the basin are apt to trap seismic waves and produce much stronger ground motion, basin edge and areas with deep sediments are also characterized with large amplification. Then, basin with softer soil deposits produces stronger surface waves with lower propagation velocity and higher mode.

Reply to P.J. Leary et al

We thank Leary et al for their thoughtful comments regarding our article. Because a growing number of survivors of childhood cancer who have received treatment that may damage the heart and/or lungs are now aging through early and middle adulthood, it is increasingly important to thoroughly describe the onset and trajectory of cardiopulmonary toxicity, the second most common cause of treatment-related mortality in aging survivors. Our data suggest that some survivors, on the continuum of progression to cardiopulmonary failure, may develop pulmonary hypertension. We hope that by documenting this next stage of cardiopulmonary failure, we have highlighted the need for additional research that identifies the etiology of pulmonary hypertension in this population and establishes directions for therapeutic intervention. We strongly agree with Leary et al that the results of our study should not be misinterpreted as an analysis of the frequency of pulmonary arterial hypertension (WHO group I pulmonary hypertension) among adult survivors of childhood cancer. As Leary et al state, the current analysis suggests that left-sided heart failure may be the etiology of the increased tricuspid regurgitant jet velocity, consistent with WHO Group II pulmonary hypertension. However, it is notable that the analysis also suggests that pulmonary hypertension was associated specifically with chest-directed radiotherapy, but not anthracycline exposure, a common cause of left-sided heart failure among adult survivors of childhood cancer. There remains the possibility that direct radiation injury to the pulmonary arterial vasculature (WHO group I, pulmonary arterial hypertension) may contribute to the etiology of the current findings. The potential for direct vascular injury from radiotherapy is well established. Additionally, direct radiation to the lung parenchyma (WHO group III) may also contribute. Our survivor population was evaluated using the Children’s Oncology Group Long-Term Follow-Up Guidelines for Survivors of Childhood, Adolescent, and Young Adult Cancers. Thus, pulmonary function testing was not performed on all of the participants in our study, which reduces the statistical power of our analysis to determine the contribution of direct pulmonary injury. Future research should incorporate a complete assessment of pulmonary function among survivors who are at risk of treatment-associated cardiac dysfunction to further define the potential contribution of pulmonary toxicity in the observed elevations in tricuspid regurgitant jet velocity. We also agree with Leary et al that research collaboration among oncologists, cardiologists, and pulmonary vascular experts will be necessary to unravel the potentially complex etiology of elevated tricuspid regurgitant jet velocity among adult survivors of childhood cancer. Right heart catheterization augmented by exercise testing will be the next step in validating these findings, determining etiology, and most importantly, directing appropriate medical therapy. More comprehensive evaluation and continued follow-up of the St Jude Lifetime Cohort will allow us to clarify these issues and determine the impact of elevated tricuspid regurgitant velocity on subsequent morbidity and mortality.

Metal Flow Velocity in an Intake Port in the Process of Die Casting

The paper deals with metal flow velocity in an intake port in the process of die casting. In the theoretical part the author defines theoretical knowledge from the field of the mold cavity filling regime and the velocity of pressing the melt into the mold cavity. The practical part focuses on the impact of metal flow velocity in an intake port and the filling regime of the pressure foundry mold cavity, related to the former, on the homogeneity of the casting.

Control of self-assembly defects in thermal nanoimprint

With residual-free imprint, physical self-assembly of the polymer within partly-filled cavities has to be avoided to ensure the masking capability of nanoimprint when used as a lithography technique. In this regard we investigate the impact of the velocity of pressure application by use of a motor-driven imprint system. Slowing-down the velocity of pressure application maintains a smooth surface of the polymeric layer in the cavities, minimizing the risk of local contact between polymer and stamp with moderate filling levels of the cavities. At a high filling level of the cavities, the formation of self-assembly cannot be avoided, as van der Waals interactions between polymer surface and stamp become effective to drive the formation of instabilities. The experimental results obtained can be understood by stability analysis. Understanding of the processes leading to the formation of physical self-assembly is vital to exploit the full potential of nanoimprint for processing.

Compression of Characteristics of Trajectories in Rotating Frames vs. Nonuniform Magnetic Fields

The equation of motion of an object moving in a frictionless horizontal rotating frame is somewhat comparable to the one describing the motion of a point-like charged particle projected in a magnetic field. We show that the impact of angular velocity in the former is equivalent to the impact of the magnetic field in the latter. We consider scenarios conducive to comparable trajectories for these two distinct areas of physics. We extend the analysis considering two separate routes. For the rotating frame we investigate the impact of friction and for the magnetic field the effect of field in-homogeneities. We utilize Mathematica [1] throughout, most notably for solving coupled partial differential equations.

Thoracic injuries sustained by severely injured front-seat passengers and drivers: injury patterns and their relationship to crash characteristics

Thoracic injuries are common in vehicle crashes, but only a few studies thus far have analysed the relationship between injury characteristics and collision details and discussed the possible implications for future vehicle design and prevention. In this study, the crash details were prospectively collected at the scene of injury between 2004 and 2009 for severely injured patients. The collected data included the type of collision, angle of impact and change of velocity on impact as well as injury characteristics and patient demographics, including abbreviated injury scale (AIS) and injury severity score (ISS).There were 5998 accidents involving 8830 patients over this five-year period; 31 met the inclusion criteria (23 males and eight females). The mean ISS was 37 ± 12.68, the mean AIS Thorax was 4.0. Lung contusions were found in 90% of the patients, pneumothoraces in 58% and rib fractures in 81%. There was a significant relationship between accident deceleration speed (ΔV), AIS Thorax (p = 0.02) and the incidence of pneumothoraces (p = 0.046). The analysis showed a high overall incidence of thoracic injuries in car passengers. Future improvements in automobile safety and design should seek to reduce the incidence of thoracic injuries by uniform vehicle deformation and further implementation of side airbags.