涡流压力脉动线的终结

用简单的制造工艺加工的回收转环是混流式水轮机设计中控制尾水管中不期望有的脉动和旋涡的有效方法。

长陆PL7300电涡流压力变送器和射频电容物位计

珠海长陆工业自动控制系统有限公司引进法国先进技术开发出填补国内空白的新型电子液位测量仪：PL7300智能电涡流液位传感器并已申报专利。

压力涡流喷油器喷嘴结构因素对喷雾特性的影响

采用MIXTURE双相流数值模拟的方法研究压力涡流喷嘴结构因素对形成中空锥喷雾的影响。喷孔直径由0．5mm增大到1mm时，喷雾贯穿距离减少约60％，空心锥角增大7．5倍；喷孔长度由0．6mm增大到1mm时，喷雾贯穿距离增大约1．4倍，空心锥角减少约40％；有轴针时，空心锥角增加约4倍；改变轴针形状，将轴针头部加工成锥形，空心锥角增加约30％。喷孔内、外有无圆角对喷雾空心锥角大小的影响幅度在30％-40％。研究结果表明：喷孔长径比、喷孔入口处喷孔形状与轴针形状的配合和喷孔出口端形状是影响压力涡流喷嘴空心锥特性的重要因素。

燃烧室背压对压力涡流喷嘴喷雾特性的影响

采用高速摄影技术、激光测粒仪和PIV测试技术系统试验研究了燃烧室背压对斯特林发动机压力涡流喷嘴喷雾形成过程、贯穿距离增长规律、喷雾锥角、液滴粒径和喷雾流场的影响。结果表明,燃烧室背压的增加使喷雾形状更加致密,贯穿距离的增加变缓,液滴平均速度增加,索特平均直径增加。当燃烧室背压大于1.0-1.5 MPa之间的一个临界值时,其对喷雾锥角没有影响,小于此临界值,燃烧室背压的增加会使喷雾锥角急剧降低。

斯特林发动机压力涡流喷嘴的喷雾特性试验

采用高速摄影技术,研究了斯特林发动机压力涡流喷嘴的喷雾发展过程及喷雾特性,并考察了喷射压力和气体引射对喷雾特性的影响.结果表明,压力涡流喷嘴初始喷雾阶段雾化效果较差,持续时间较短,主喷雾发展过程有明显的空气卷吸涡流现象;柴油主喷雾锥角随喷油时间先迅速增大后逐渐减小至稳定,而贯穿距离则逐渐增大至稳定,喷雾锥角随喷油压力的提高而增大;引射空气对稳态喷雾形态有明显影响,使得喷雾扩散范围明显扩大,油气混合更加充分.

压力涡流喷嘴雾化特性模拟的双相流模型分析

与直射式压力喷嘴模拟计算相比,燃油在喷嘴出口断面处的速度方向成为模拟压力涡流喷嘴喷雾特性时需要特别考虑的问题。对现有的双相流计算模型进行了分析,分析结果表明:广泛用于压力喷嘴模拟计算的欧拉-拉格朗日法,并不适于压力涡流喷嘴出口区附近的喷雾模拟计算。喷嘴出口处采用VOF模型,在适当的下游处再采用欧拉-拉格朗日模型计算压力涡流喷嘴的喷雾特性是一个相对合理的选择。采用这种方法需要特别考虑的问题是:两种模型如何衔接。

涡流纺纱线的包缠加捻对其力学性能的影响

为探究涡流纺纱线的包缠加捻与成纱力学性能的关系,从理论上分析了涡流纺纱线拉伸过程中的纤维形变与受力,详细研究了涡流压力和纺纱速度对涡流纺纱线力学性能的影响。结果表明:外层纤维螺旋包缠特性对涡流纺成纱的力学性能起着决定性作用,涡流压力和纺纱速度为影响涡流纺包缠和加捻效果的主要因素;当纺纱速度为280 m/min时,随着涡流压力的增加,涡流纺纱线的断裂比强度和弹性模量呈先增加后下降的变化趋势,而断裂伸长率基本不变,且当涡流压力为0.55 MPa时,涡流纺成纱力学性能最优;当涡流压力恒定为0.45 MPa时,随着涡流纺纱速度的增加,涡流纺纱线的断裂比强度、断裂伸长率均呈略微下降趋势,弹性模量呈现先下降后基本不变的趋势。

超声波淬火对20Mn2A钢力学性能的影响

对20Mn2A的超声波淬火工艺进行了研究,并对显微组织和力学性能进行了分析。结果表明:硬度、强度和耐磨性随超声波涡流压力的升高而增加,伸长率随超声波涡流压力的升高而下降,超声波淬火后的显微组织是细小的板条马氏体。在100 N、300 r/min及1000 s的实验条件下,2.0、2.5和3.0 MPa超声波涡流压力淬火后的试样具有最小的磨损质量损失,耐磨性能良好。

空气引射对斯特林发动机火焰特征及燃烧温度的影响

为了研究空气引射对斯特林发动机常压燃烧特性的影响,在可视化试验台上进行了不同工况下的燃烧试验,并利用高速摄影机拍摄了燃烧室内的火焰图像,利用热电偶测量了燃烧室内的燃烧温度.结果表明,无空气引射时,燃烧火焰较长,张角较小,波动较大,高温区集中在燃烧室轴线附近;加入适量引射空气,火焰缩短,张角增大,稳定性提高,高温区外扩,位置向喷嘴靠近,燃烧温度升高;过量引射空气使火焰失稳,温度场紊乱,高温区分散,燃烧温度下降.

斯特林发动机喷雾特性试验研究

采用高速摄影技术研究比较了不同背压下斯特林发动机的喷雾过程,并分析了燃油流量、燃烧室背压以及喷嘴参数对斯特林发动机喷雾特性的影响。结果表明,燃烧室背压对喷雾过程具有明显的影响;随着流量的增大,贯穿距离和喷雾锥角都增大,但流量达到一定程度后,喷雾锥角的增加趋势减缓;随着燃烧室背压加大,喷雾的贯穿距离增大,喷雾锥角减小,背压对喷雾具有压缩作用,当背压增大到一定程度后,它对喷雾锥角的影响程度降低;相同流量工况下,随喷嘴流道通径的减小,喷雾的贯穿距离增大,喷雾锥角减小。

Influence of bluff body shape on wall pressure distribution in vortex flowmeter

To investigate the influence of bluff body shape on wall pressure distribution in a vortex flowmeter,experiments were conducted on a specially designed test section in a closed water rig at Reynolds numbers of 6.2×10 4-9.3×10 4.The cross sections of the bluff bodies were semicircular,square,and triangular shaped,and there were totally 21 pressure tappings along the conduit to acquire the wall pressures.It is found that the variation trends of wall pressures are basically identical regardless of the bluff body shapes.The wall pressures begin to diverge from 0.3D(D is the inner diameter of the vortex flowmeter) in front of the bluff body due to the diversity in shape,and all reach the minimum values at 0.3D behind the bluff body.A discrepancy between the triangular or square cylinder and the semicircular cylinder in wall pressure change is observed at 0-0.1D behind the bluff body.It is also found that the wall pressures and irrecoverable pressure loss coefficients increase with flow rates,and the triangular cylinder causes the smallest irrecoverable pressure loss at a fixed flow rate.

Recent development of vortex method in incompressible viscous bluff body flows

Vortex methods have been alternative tools of finite element and finite difference methods for several decades. This paper presents a brief review of vortex method development in the last decades and introduces efficient vortex methods developed for high Reynolds number bluff body flows and suitable for running on parallel computer architectures. Included in this study are particle strength exchange methods, core-spreading method, deterministic particle method and hybrid vortex methods. Combined with conservative methods, vortex methods can comprise the most available tools for simulations of three-dimensional complex bluff body flows at high Reynolds numbers.

Effects of stator bending on pressure field and loss of transonic turbine stage

To study effects of the upstream flow field changing on the downstream flow field of transonic turbine, different three-dimensional bowed blades, which are the stator blades of transonic turbine stage, were designed in this paper. And then numerical calculations were carried out. The effects on downstream flow field were studied and analyzed in detail. Results show that, at the middle of stator blades, although the increasing Maeh number causes the increase of shock-wave strength and friction, the middle flow field of downstream rotors is improved obviously. It is an important change in transonic condition. This causes the loss of the rotor＇ s middle part decreased greatly. Correspondingly, efficiency of the whole transonic stage can be increased.

Control of Vortex Shedding and Drag Reduction through Dual Splitter Plates Attached to a Square Cylinder

In this paper we have made a numerical study on the control of vortex shedding and drag reduction of a cylinder by attaching thin splitter plates. The wake structure of the cylinder of square cross-section with attached splitter plates is analyzed for a range of Reynolds number, based on the incident stream and height of the cylinder, in the laminar range. The Navier-Stokes equations governing the flow are solved by the control volume method over a staggered grid arrangement. We have used the semi-implicit method for pressure-linked equation （SIMPLE） algorithm for computation. Our results show that the presence of a splitter plate upstream of the cylinder reduces the drag, but it has a small impact on the vortex shedding frequency when the plate length is beyond 1.5 time the height of the cylinder. The presence of a downstream splitter plate dampens the vortex shedding frequency. The entrainment of fluid into the inner side of the separated shear layers is obstructed by the downstream splitter plate. Our results suggest that by attaching in-line splitter plates both upstream and downstream of the cylinder, the vortex shedding can be suppressed, as well as a reduction in drag be obtained. We made a parametric study to determine the optimal length of these splitter plates so as to achieve low drag and low vortex shedding frequency.

超声波淬火对34SiMnK钢力学性能的影响

对34Si Mn K钢在0~3 MPa涡流压力下的超声波淬火工艺进行了研究,并对其显微组织和力学性能进行了分析。结果表明,试验钢冲击性能和磨损量随着超声波涡流压力的升高而降低,硬度和抗拉强度随着超声波涡流压力的升高而增加;2.5 MPa涡流压力超声波淬火后得到的显微组织是细小的板条马氏体;在100 N-300 r/min-1200 s的试验条件下,分别在2.5和3.0 MPa超声波涡流压力下,淬火后的试样的磨损量最小,耐磨性能良好。

Flow Fields with Vortex in a Small Semi-open Axial Fan

In order to clarify the effect of tip clearance （TC） size on fan performance and the flow field at rotor outlet in a small semi-open axial fan, the experimental investigation was carried out. The tip diameter of test fan rotor was 180mm and test TC sizes were lmm （TC=1mm） and 4mm （TC=4mm）. Fan characteristics tests were carried out for two cases of TC size and three-dimensional velocity fields at rotor outlet were measured using a single slant hot-wire probe at four flow-rate conditions. As a result, it was found that the pressure - flow-rate characteristics curves for two cases showed almost the same tendency. However, the ensemble averaged velocity profiles along radial measurement stations of TC-4mm largely changed compared with that of TC=1mm in cases of small flow-rate condition. From the phase-locked averaging results, it was also found that the vortex existed in the rotor outlet flow field of high flow-rate condition for each TC case. Compared with the vortices for TC=1mm and TC=4mm, the vortex for TC=4mm was stronger than that for TC=1mm.

Simulation of shock wave buffet and its suppression on an OAT15A supercritical airfoil by IDDES

In the present paper,extremely unsteady shock wave buffet induced by strong shock wave/boundary-layer interactions (SWBLI) on the upper surface of an OAT15A supercritical airfoil at Mach number of 0.73 and angle of attack of 3.5 degrees is first numerically simulated by IDDES,one of the most advanced RANS/LES hybrid methods.The results imply that conventional URANS methods are unable to effectively predict the buffet phenomenon on the wing surface;IDDES,which involves more flow physics,predicted buffet phenomenon.Some complex flow phenomena are predicted and demonstrated,such as periodical oscillations of shock wave in the streamwise direction,strong shear layer detached from the shock wave due to SWBLI and plenty of small scale structures broken down by the shear layer instability and in the wake.The root mean square (RMS) of fluctuating pressure coefficients and streamwise range of shock wave oscillation reasonably agree with experimental data.Then,two vortex generators (VG) both with an inclination angle of 30 degrees to the main flow directions are mounted in front of the shock wave region on the upper surface to suppress shock wave buffet.The results show that shock wave buffet can be significantly suppressed by VGs,the RMS level of pressure in the buffet region is effectively reduced,and averaged shock wave position is obviously pushed downstream,resulting in increased total lift.

Interaction between Struts and Swirl Flow in Gas Turbine Exhaust Diffusers

The increasing use of gas turbines in combined cycle power plants together with the high amount of kinetic energy in modem gas turbine exhaust flows focuses attention on the design of gas turbine diffusers as the connecting part between the Brayton/Joule and the Rankine parts of the combined cycle. A scale model of a typical gas turbine exhaust diffuser is investigated experimentally. The test rig consists of a radial type, variable swirl generator which provides the exhaust flow corresponding to different gas turbine operating conditions. Static pressure measurements are carried out along the outer diffuser walls and along the hub of the annular part and along the centerline of the conical diffuser. Velocity distributions at several axial positions in the annular and conical diffuser have been measured using a Laser Doppler Velocimeter （LDV）. Pressure recovery coefficients and velocity profiles are depicted as a function of diffuser length for several combinations of swirl strength, tip flow and strut geometries. The diffuser without struts achieved a higher pressure recovery than the diffuser with struts at all swirl angle settings. The diffuser with cylindrical struts achieved a higher pressure recovery than the diffuser with profiled struts at all swirl angle seO.ings. Inlet flows with swirl angles over 18° affected the pressure recovery negatively for all strut configurations.

On the Pressure Drop and the Velocity Distribution in the Cylindrical Vortex Chamber with Two Inlet Pipes for the Control of Vortex Flow

Vortex flow is applied to a cyclone dust collector, a vortex combustion chamber, and a vortex diode for vortex control. In order to apply the vortex flow to the industries, it is necessary to keep the stable flow condition and to estimate the response time of the transient flow process and also the intensity of the vortex flow. For control vortex flow, two types of vortex chamber with two inlet pipes were designed. One of them is to promote the vortex flow named as Co-Rotating Flow System and another one is to hinder the vortex flow named as Counter-Rotating Flow System. The pressure drops and the velocity distributions were measured for these vortex chambers. The estimation of the tangential velocity by the application of the angular momentum flux is compared with the measured velocity by a cylindrical Pitot-tube. The characteristics of the total pressure drop could be explained by introducing the circulation.

Flow Control Effect on Unsteadiness of Shock Wave Induced Separation

In usual cases of significant pressure gradients and strong shocks, the front shock takes a fixed location along the wall, at which separation starts. Usually the rear shock is responding to vortex sheding by its deflection angle. In consequence main shock and rear shocks are moving whilst front shock is stable. The goal of the measurements presented here is to find out how the k-foot behaves during shock oscillations in the case when front shock is not fixed by the pressure gradient. Unsteady shock behaviour is also investigated when air jet vortex generators （AJVG） are used. Counteraction of the separation is directly related to the influence on unsteady processes in the shock wave induced separation.