Transient simulation of a pump-turbine with misaligned guide vanes during turbine model start-up

Experimental studies of a model pump-turbine S-curve characteristics and its improvement by misaligned guide vanes （MGV） were extended to prototype pump turbine through 3-D transient flow simulations. The unsteady Reynolds-averaged Navier-Stokes equations with the SST turbulence model were used to model the transient flow within the entire flow passage of a reversible pump-turbine with and without misaligned guide vanes during turbine model start-up. The unstable S-curve and its improvement by using misaligned guide vane were verified by model test and simulation. The transient flow calculations were used to clarify the variations of pressure pulse and internal flow behavior in the entire flow passage. The use of misaligned guide vanes can eliminate the S-curve characteristics of a pump-turbine, and can significantly increase the pressure pulse amplitude in the entire flow passage and the runner radial forces during start-up. The MGV only decreased the pulse amplitude on the guide vane suction side when the rotating speed was less than 50% rated speed. The hydraulic reason is that the MGV dramatically changed the flow patterns inside the entire flow passage, and destroyed the symmetry of the flow distribution inside the guide vane and runner.

Influence of propagation direction on operation performance of rotating detonation combustor with turbine guide vane

Due to the pressure gain combustion characteristics,the rotating detonation combustor(RDC)can enhance thermodynamic cycle efficiency.Therefore,the performance of gas-turbine engine can be further improved with this combustion technology.In the present study,the RDC operation performance with a turbine guide vane(TGV)is experimentally investigated.Hydrogen and air are used as propellants while hydrogen and air mass flow rate are about 16.1 g/s and 500 g/s and the equivalence ratio is about 1.0.A pre-detonator is used to ignite the mixture.High-frequency dynamic pressure transducers and silicon pressure sensors are employed to measure pressure oscillations and static pressure in the combustion chamber.The experimental results show that the steady propagation of rotating detonation wave(RDW)is observed in the combustion chamber and the mean propagation velocity is above 1650 m/s,reaching over 84%of theoretical Chapman-Jouguet detonation velocity.Clockwise and counterclockwise propagation directions of RDW are obtained.For clockwise propagation direction,the static pressure is about 15%higher in the combustor compared with counterclockwise propagation direction,but the RDW dominant frequency is lower.When the oblique shock wave propagates across the TGV,the pressure oscillations reduces significantly.In addition,as the detonation products flow through the TGV,the static pressure drops up to 32%and 43%for clockwise and counterclockwise propagation process respectively.

Erosion Characteristics of Hydraulic Turbine Guide-Vane End Clearance in Sediment Water Flow: A Simplified Model Analysis

The effect of clearance flow on the erosion characteristics of a circular cylinder with a backward facing step in sediment-laden water flow is analyzed numerically with the mixture model and the re-normalization group (RNG) k-ε turbulence model. Thirty-six monitoring points are set up on different stream surfaces to collect information on the impact erosion under different flow conditions, where the Initial Sediment Volume Fraction (ISVF) is set to 0.05, 0.075, 0.1, 0.125, and 0.15;particle diameter is set to 0.05 mm, 0.15 mm, 0.25 mm, 0.35 mm, and 0.45 mm respectively. The distribution of particle velocity and Local Solid-Phase Volume Fraction (LSVF) along different stream surfaces are calculated, based on which the trend of erosion is qualitatively evaluated. ISVF and particle diameter play different roles on the impact erosion index parameter () on the different wetted walls. Relative wear rate of numerical estimation agrees well with the practical one under the same working condition. Numerical analysis demonstrates that guide vane with a negative curvature end surface (concave surface) can decrease erosion damage effectively, which may provide a reference for optimal design and maintenance of hydraulic turbine.

Turbine Passage Secondary Flow Dynamics and Endwall Heat Transfer Under Different Inflow Turbulence

This study presents endwall hydrodynamics and heat transfer in a linear turbine cascade at Re 5×105 at low and high intensities of turbulence.Results are numerically predicted using the standard SST model and Reθ-γtransition model as well as using the high-resolution LES separately.The major secondary flow components,comprising the horseshoe,corner,and passage vortices are recognized and the impact on heat or mass transfer is investigated.The complicated behavior of turbine passage secondary flow generation and establishment are impacted by the perspective of boundary layer attributes and inflow turbulence.The passage vortex concerning the latest big leading-edge vane is generated by the enlargement of the circulation developed at the first instance adjacent to the pressure side becomes powerful and mixes with other vortex systems during its migration towards the suction side.The study conclusions reveal that substantial enhancements are attained on the endwall surface,for the entire spanwise blade extension on the pressure surface,and in the highly 3-D region close to the endwall on the suction surface.The forecasted suction surface thermal exchange depicts great conformity with the measurement values and precisely reproduces the enhanced thermal exchange owing to the development and lateral distribution of the secondary flows along the midspan of the blade passage downstream.The impacts of the different secondary flow structures on the endwall thermal exchange are described in depth.

Guide Vane with Current Plate to Improve Efficiency of Cross Flow Turbine

To get the sustainable society, the hydropower with not only the large but also the small/mini/micro capacities has been paid attention to in the power generation. The cross flow turbine can work effectively at the comparatively low head and/or low discharge, then the runner and the turbine profile has been optimizing. In this paper, the model turbine was prepared in accordance with the traditional design, and the performance and the flow condition were investigated experimentally at the various operating conditions. The hydraulic efficiency is doubtlessly maximal while the guide vane is at the normal/design position, and deteriorates in the lower discharges adjusted by the guide vane. Such deteriorations are brought from the unacceptable flow conditions in the inlet nozzle. To improve the efficiency dramatically in the lower discharge, the guide vane installed in the inlet nozzle was equipped with the current plate, and the fruitful effects of the plate on the efficiency were confirmed experimentally.

2D Model of Guide Vane for Low Head Hydraulic Turbine： Analytical and Numerical Solution of Inverse Problem

Low-head hydraulic turbines are the subjects to individual approach of design. This comes from the fact that hydrological conditions are not of a standard character. Therefore, the design method of the hydraulic turbine stage has a great importance for those who may be interested in such an investment. As a first task in a design procedure the guide vane is considered. The proposed method is based on the solution of the inverse problem within the flame of 2D model. By the inverse problem authors mean a design of the blade shapes for given flow conditions. In the paper analytical solution for the simple cylindrical shape of a guide vane is presented. For the more realistic cases numerical solutions according to the axis-symmetrical model of the flow are also presented. The influence of such parameters as the inclination of trailing edge, the blockage factor due to blade thickness, the influence of loss due to dissipation are shown for the chosen simple geometrical example.

Two Concepts of Guide Vane Profile Design for a Low Head Hydraulic Turbine

Two concepts of the guide vanes channels design for a low head hydraulic turbine were investigated using 2D and 3D models. Model 2D was used to generate the geometry of profiles which form a blade channel. After that by means of 3D commercial code （ANSYS/Fluent v. 15）, the designed cascades were examined. The characteristic parameters of compared guide vanes have been presented. The problem of low head hydraulic turbine design is important from the technical point of view for usually not typical environmental circumstances, in which the hydropower plants are planned.

Influence of Endwall Contouring on the Secondary Flow in Turbine Nozzle Guide Vane

Numerical simulations are carried out to investigate the effect of the endwall contouring on the secondary flow in turbine nozzle guide vane.The three contoured cascades with the same contouring profile and the different positions where the contoured profile locates at are researched.The results show that the contouring configuration can reduce the aerodynamic losses of the cascade.The flat side takes advantage of a stronger decrease of the losses,compared to the contoured side.The contouring configuration can also inhibit the secondary flow.The contoured cascade in which the contouring profile starts upstream of the airfoil,ends at the middle of the airfoil has the best effect of improving secondary flow.

Improving the Energy Performance of a High-Pressure Hydraulic Turbine by Researching the Flow in the Flow Part

In this study, the goal is to increase the efficiency of a high-pressure hydraulic turbine. The goal is achieved by numerical flow simulation using CFX-TASCflow. This approach reduces costs and time compared to the experimental approach and allows for improving the turbine productivity and its design. The analysis of energy losses in the flow part of the turbine Fr500, as well as the analysis of the influence of the opening of the guide vanes on changes in energy losses. The results showed that the greatest losses occur in the guide vane 3.02% based on the two-dimensional model and 2.5% based on the 3D model, which significantly affects the efficiency. The analysis was carried out using programs for calculating fluid flow in two-dimensional and three-dimensional formulations. With the help of the study, the main energy problem is solved—increasing efficiency.

船用燃机涡轮导叶扇形叶栅气动性能试验研究

为了验证全三维优化设计效果,并探索适用于船用燃气轮机工作特点的叶型,利用扇形涡轮叶栅试验台,针对某船用燃气轮机原型和改型两套涡轮导叶,开展了不同攻角下的扇形叶栅气动性能试验。应用五孔探针、叶片表面静压测量孔,分别测量了叶栅出口流场、不同叶高处叶片型面的压力,分析了导叶出口截面速度场及总压损失分布,导叶根、中、顶这3个截面压力分布,以及节距平均出口气流角、总压损失系数沿叶高分布等。优化前后试验结果对比分析表明:经优化改型后,沿叶高方向导叶表面压力分布更趋均匀化,叶片后部加载特征更加明显,在试验攻角范围内(-10°~+10°)导叶总压损失系数明显减小,且攻角变化对损失影响较小。结果表明,导叶该型是成功的,改进后的导叶对变工况的适应性更加优良,非常适合用于工况变化较为频繁的船用燃气轮机。

Improvement of Film Cooling Design for Turbine Vane Leading Edge Considering Combustor Outflow

As the interaction between the combustor and the turbine in the aero-engine continues to increase,the film cooling design considering the combustor swirling outflow has become the research focus.The swirling inflow and high-temperature gas first affect the vane leading edge(LE).However,no practical improved solution for the LE cooling design has been proposed considering the combustor swirling outflow.In this paper,the improved scheme of showerhead cooling is carried out around the two ways of adopting the laid-back-fan-shaped hole and reducing the coolant outflow angle.The film cooling effectiveness(η) and the coolant flow state are obtained by PSP(pressure-sensitive-paint) and numerical simulation methods,respectively.The research results show that the swirling inflow increases the film distribution inhomogeneity by imposing the radial pressure gradient on the vane to make the film excessively gather in some positions.The showerhead film cooling adopts the laid-back-fan-shaped hole to reduce the momentum when the coolant flows out.Although this cooling scheme improves the film attachment and increases the surface-averaged film cooling effectiveness(η_(sur)) by as much as15.4%,the film distribution inhomogeneity increases.After reducing the coolant outlet angle,the wall-tangential velocity of the coolant increases,and the wall-normal velocity decreases.Under the swirl intake condition,both ηand the film distribution uniformity are significantly increased,and the growth of η_(sur) is up to 16.5%.This paper investigates two improved schemes to improve the showerhead cooling under the swirl intake condition to provide a reference for the vane cooling design.

Thermodynamic Performance Analysis of E/F/H-Class Gas Turbine Combined Cycle with Exhaust Gas Recirculation and Inlet/Variable Guide Vane Adjustment under Part-Load Conditions

Exhaust gas recirculation control(EGRC),an inlet air heating technology,can be utilized in combination with inlet/variable guide vane control(IGV/VGVC) and fuel flow control(FFC) to regulate the load,thereby effectively improving the part-load(i.e.,off-design) performance of the gas turbine combined cycle(GTCC).In this study,the E-,F-,and H-Class EGR-GTCC design and off-design system models were established and validated to perform a comparative analysis of the part-load performance under the EGR-IGV-FFC and conventional IGV-FFC strategies in the E/F/H-Class GTCC.Results show that EGR-IGV-FFC has considerable potential for the part-load performance enhancement and can show a higher combined cycle efficiency than IGV-FFC in the E-,F-,and H-Class GTCCs.However,the part-load performance improvement in the corresponding GTCC was weakened for the higher class of the gas turbine because of the narrower load range of EGR action and the deterioration of the gas turbine performance.Furthermore,EGR-IGV-FFC was inferior to IGV-FFC in improving the performance at loads below 50% for the H-Class GTCC.The results obtained in this paper could help guide the application of EGR-IGV-FFC to enhance the part-load performance of various classes of GTCC systems.

基于变桨技术余压水轮机导叶控制方法研究

在管道压力方面,通过消耗大量的能量为水提供动能,但整体对能量的回收率较低,利用小,仍然有大量优质余压未能得到充分利用,其中余压发电的最优方案是通过水轮机进行发电,为了研究余压发电水轮机叶轮的最大使用效率和水头的最大利用率,设计了可变桨式向心涡轮水轮机,采用自适应模糊变桨控制器控制导叶开度,针对向心涡轮水轮机在相同流量、水头下导叶开度对水头利用率和叶轮效率的影响。试验基于RNG k-ω模型,构建导叶开度测试平台,采用CFD分析的方式建立水轮机导叶的模型,对可变桨式水轮机进行仿真计算,利用自适应模糊变桨控制器控制导叶,使水流进入水轮机的相对速度与叶片更贴合,通过实验验证,以轴功率为衡量指标,仿真结果表明,自适应模糊变桨有更好的控制效果,能够满足调压、减压控制发电效率的目的。

Investigation on Mechanical Characteristics of Air Jet Acting on Nozzle Vanes of VNT

Extensive experimental studies are performed using force sensors to measure actuating forces of nozzle ring devices of variable nozzle turbines. Torques from pneumatic action applied onto axles of nozzle vanes have been calculated. Test results obtained through repeated experiments are quite congruent, confirming the effectiveness of this simple method. Results have indicated that, with a fixed opening angle of guide vane, pneumatic torque increases with mass flow of air jet in the turbine; moreover, under the same mass flow rate, torque decreases with reducing opening angle, even possibly change direction down to negative. The results have also provided a modus operandi for designing nozzle-adjusting devices as well as validation data for numerical study on changes of pneumatic torque onto guide vanes under full engine operating conditions.

改变导叶翼型对水泵水轮机“S”特性的影响

针对水泵水轮机“S”特性区域的不稳定性问题,提出使用改型活动导叶翼型进行性能提升.以某水泵水轮机模型为研究对象,采用SST k-ω湍流模型对水泵水轮机全流道进行三维数值计算,通过对活动导叶翼型的改型设计,得出流量-转速模拟曲线,分析水泵水轮机组“S”特性改善情况.将计算与试验结果进行对比,并对改型活动导叶翼型前后机组的无叶区进行压力脉动分析.结果表明:在保证整体效率依然保持在92%附近的前提下,新的活动导叶翼型对机组的“S”特性依旧具有改善效果;无叶区压力脉动主要是受到活动导叶叶栅区域的分流在此重新聚集影响,并且与转轮叶片的动静相互扰动引起的;改型后的活动导叶降低了无叶区的压力脉动幅值,提升了水泵水轮机运行中的并网稳定性.

导叶几何参数对液力透平压力脉动的影响

为提高导叶式液力透平的运行稳定性,研究导叶几何参数对液力透平压力脉动的影响。在IS80-50-315型低比转速离心泵反转作液力透平叶轮进口前添加径向导叶,对导叶出口角、叶片数和径向高度采用正交试验设计的方法匹配相同叶轮形成新的液力透平模型,利用CFX软件在蜗壳内、导叶与叶轮间隙和叶轮上沿周向设置监测点进行定常和非定常数值计算,对定常计算结果进行极差分析,得出导叶几何参数对液力透平性能影响的主次因素,形成最优方案组合,并对非定常数值计算压力脉动结果进行时域和频域分析。结果表明:径向导叶几何参数组合对水力效率和水头的影响均为叶片数>径向高度>出口角;导叶式液力透平的压力系数在导叶与叶轮间隙上最大,其次在叶轮上,蜗壳内部压力系数最小;当叶轮叶片数相同时,径向导叶出口角和径向高度的值在合理范围内选取较小值时,有利于降低导叶式液力透平的压力脉动幅值和提高运行稳定性。

燃气轮机可转导叶执行机构延迟特性分析

针对燃气轮机可转导叶执行机构延迟特性的问题,本文基于所搭建的物理试验台进行了可转导叶执行机构仿真和试验研究,给定可转导叶执行机构不同的位移控制信号,观测其反馈的实际位移,得出了可转导叶执行机构的延迟特性,并基于试验数据验证可转导叶执行机构仿真模型。试验结果及仿真模型机可用于提高燃气轮机考虑可转到叶影响时的动态仿真精度。

抽水蓄能机组水轮机工况启动过程内部流场分析

本文采用CFD数值模拟的方法,模拟计算了抽水蓄能机组在水轮机工况启动过程内部流场特征。得到了在活动导叶开启过程中的速度、压力随时间的瞬态分布规律,讨论了蓄能机组开启过程中外特性的变化曲线。结果表明:活动导叶的开启规律可以大体分为五个阶段。活动导叶的开启规律是先缓慢开启,然后以较快的速度关闭,最后再保持到空载的开度,从第四阶段,导叶再逐渐打开直到额定开度。转轮扭矩和机组流量呈现出先增大后减小的趋势,当导叶逐渐打开时,转轮扭矩和机组流量再逐渐上升。本文为研究蓄能机组水轮机工况下启动过程的内部流动变化提供了参考依据,同时对提高水轮机工况的启动稳定性具有重要意义。

宽雷诺数下肋参数对U型内冷通道流动与换热特性影响的实验研究

为了研究肋高和通道高的比值(e/H)、肋间距与肋高的比值(P/e)以及肋角度(α)对U型带肋通道流动与换热特性的影响,采用铜板法结合热电偶测量壁面温度分布,对6个不同肋参数U型带肋通道的表面换热特性进行了实验研究。带肋通道截面为正方形,实验的Re为5.0×10^(3)~1.0×10^(5)。研究结果表明,随着e/H和Re的增大,带肋通道的对流换热系数逐渐增大,但相应的流动损失增幅明显,e/H从0.08增大到0.12时,通道的阻力系数增大了近一倍。对于e/H=0.08的通道,P/e分别为6、8、10时,P/e为8时的对流换热系数和阻力损失均高于其他两种情况。相较于90°正交肋,带角度的斜肋能够进一步增强带肋通道的对流换热,75°肋的强化效果略强于60°肋。在实验参数范围内,对于几种不同的带肋U型通道,对流换热系数为光滑通道的1.9~3.0倍,阻力系数为光滑通道的4~16倍。综合考虑换热与流阻,e/H=0.08、P/e=8、α=45°的通道性能最好。

烟气再循环联合循环中燃气轮机温度控制方案

在部分负荷工况下,采用余热锅炉排气再循环与压气机进口导叶调节联合应用(EGR-IGVC)策略,可有效改善燃气轮机联合循环性能.但此策略若配合联合循环电站部分负荷工况中燃气轮机常采用的等T3(透平入口温度)-T4_(m)(透平排气温度最大允许值)温控方案,在较低负荷下会造成较大的底循环[火用]损失,底循环做功能力下降明显.提出了一种更适用于EGR-IGVC策略的等T3-T4_(m)-T4_(d)(透平排气温度设计值)温控方案,以PG9351FA型燃气轮机联合循环为研究对象,采用能量与[火用]分析方法,对比研究了EGR-IGVC策略配合两种温控方案时的联合循环部分负荷性能.研究结果表明,当环境温度为15℃,部分负荷率在80%负荷以上时,EGR-IGVC策略配合等T3-T4_(m)方案效果仍为最佳;在30%~80%负荷时,与配合等T3-T4_(m)方案相比,EGR-IGVC策略配合等T3-T4_(m)-T4_(d)方案可使燃气轮机效率提高0.15~0.47个百分点,余热锅炉[火用]损失减少0.51%(2.15 MW)以上.研究亦表明,当环境温度在0~40℃间变化时,采用等T3-T4_(m)-T4_(d)方案总能获得更高的联合循环效率,且随环境温度上升,部分负荷效率增幅更为明显.