Effects of Number of Bleed Holes on Shock-Wave/Boundary-Layer Interactions in a Transonic Compressor Stator

An extensive numerical investigation is conducted to characterize the flow separation control in a transonic compressor cascade with a porous bleed.The bleed holes are arranged on the suction surface in a single row,two staggered rows and three staggered rows.For each bleed scheme,five bleed pressure ratios are examined at an inlet Mach number of 1.0.The results indicate that the aerodynamic performance of the cascade is significantly improved by the porous bleed.For the single-row scheme,the maximum reduction in total pressure losses is 57%.For the two-staggered-row and three-staggered-row schemes,there is an optimal bleed pressure ratio of 1.0,and the maximum reductions in total pressure loss are 68% and 75%,respectively.The low loss in the cascade is due to the well-controlled boundary layer.The new local supersonic region created by the bleed hole is the key reason for the improved boundary layer.The vortex induced by side bleeding provides another mechanism for delaying flow separation.Increasing the bleed holes could create multiple local supersonic regions,which reduce the range of the adverse pressure gradient that the boundary layer needs to withstand.This is the reason why cascades with more bleed holes perform better.

Flow Field Improvement by Bowed Stator Stages in a Compressor with Different Axial Gaps Under Near Stall Condition

The outlet flow fields of a low-speed repeating-stage compressor with bowed stator stages are measured with five-hole probe under the near stall condition when the rotor/stator axial gap varies. The performances of the straight stator stages are investigated and compared to those of the bowed stator stages. The results show that using bowed stator stages could alleviate the flow separation at both upper and low corners of the suction surface and the endwalls, and decrease the losses along the flow passage as well as the outlet flow angle. As the rotor/stator axial gap decreases, although the diffusion capacity of the compressor increases obviously, the outlet flow field in the straight stator stages deteriorates quickly. By contrast, little changes occur in the bowed stator stages, indicating that as the rotor/stator axial gap decreases, improved performance is achieved in the bowed stator stages.

Investigation of the Vortex Dynamic Mechanism of the Flow Losses on a Transonic Compressor Stator

For a transonic axial-flow compressor, the numerical simulations, verified against experimental data, were used to study the inherent correlation between the evolutionary process of the vortex structures and the flow loss in a compressor stator passage during the throttling process. The flow loss was divided accurately and quantitatively, based on the evolutionary process of the vortex structures. According to the position of the singular points of the vortex structures, the influence of the evolution of the vortex structures on the generation and development of the flow loss was analyzed on a microscale scale. Thereafter, this paper provided the vortex dynamic mechanism of the flow loss, which was important to enrich the theoretical system of the flow field in the compressor. The results show that: the flow loss at the top of the stator tip is caused by the low-energy fluid clusters, which are transported and accumulated by the vortices from the endwall; the transport effect of the pressure separation vortex at the upper half-height only migrates the position of the flow losses, but there is new flow loss generated by its shear action to the endwall. The dominant flow loss during the throttling process concentrates upon the closed separation bubble around the middle of the suction side of the stator.

Experimental Study of Stator Clocking Effects in an Axial Compressor

This paper is focused on the experimental study of the effects of stator clocking on the performance of a low-speed repeating stage axial compressor with compound-lean stators as well as the one with conventional stators （the baseline） for comparison. The experimental results show that as the clocking positions vary, the upstream stator wake enters the following passage at different circumferential positions, and then mixes with the local fluid in the following passage. This is the main reason for the variation of the compressor performance resulted from the stator clocking effects. The variation of the compressor performance due to the clocking effect is less pronounced for the compressor with compound-lean stators than with the baseline. At a certain clocking position, the efficiency of the compressor with compound-lean stators is increased in comparison with that of the baseline, especially on small mass flow rate conditions, e.g., 0.7% at design condition and 3.5% at near-surge condition in this case. The maximum 1.22% and the minimum 0.07% increases in efficiency on design condition are obtained through the combined effects of the stator compound-lean and the stator clocking in this case.

轴流压气机可调静子叶片间隙泄漏流数值模拟

为了探究轴流压气机前面级可调静子叶片部分间隙泄漏流对压气机性能和流场的影响,通过数值方法模拟某轴流压气机带有可调静子叶片的前面级1.5级流场,并详细分析了部分间隙泄漏流特征。数值仿真结果表明,相较带容腔原型算例,部分间隙使得压气机特性线往左下方偏移,设计点效率降低0.12%,近失速点效率降低1.83%,但喘振裕度提升6.4%;可见受到部分间隙泄漏流影响,静子叶片根部出口气流角明显增加;部分间隙泄漏流可以给吸力面根部角区低能流体充能,降低设计点端壁处的损失,降低近失速点吸力面分离涡的强度,提升喘振裕度;根部部分间隙造成叶片根部做功能力降低,但影响范围控制在5%叶高以内;部分间隙造成静子根部流场发生改变,使得设计工况点静子根部产生一条附着线,并形成闭式分离。

可调静叶角度精度对多级压气机气动性能的影响

为了获得可调静叶的角度精度对多级压气机的气动性影响情况,对某11级高压压气机的S1、R2和S2共三排叶片开展了全三维数值模拟研究,通过调整S1静叶开、关角度值分析可调静叶角度偏差的量化影响。研究结果表明:可调静叶调节精度越高,则压气机越匹配设计点工况,气动性能则越好;可调静叶角度精度为±1°时对压气机的效率影响不大;但可调静叶角度精度在关闭3°时,效率损失最大达0.31%,静叶根部压力面流动分离明显增大。

交替静叶布局对轴流压气机气动稳定性的影响

为揭示交替静叶布局控制角区分离的流动机理,提升压气机性能,实现压气机的扩稳,采用了数值模拟方法对某高负荷跨声速压气机展开交替静叶设计研究。通过改变静叶叶尖进口几何角,调整叶片的布局方式,得到一种改叶型弯角交替静叶,在此基础上结合叶片弦长进一步优化,得到另一种改弦长交替静叶。数值研究表明:改叶型弯角交替静叶布局压气机的稳定裕度相对原型提升了34.7%,改弦长交替静叶使改叶型弯角交替静叶的压气机稳定性进一步提高,但会造成压比和效率的小幅下降,即以损失部分性能的代价换取了压气机稳定性的提升,改弦长交替静叶压气机在前者基础上将稳定裕度进一步提升了9.7%。新型的静叶布局使得相邻流道的流场结构产生差异,在周向上形成上、下角区分离交替分布的格局,促进了相邻流道出口流体的汇聚。叶型弯角的改变使角区低能流体区引入了更多高能流体,抑制了低能流体在角区堆积,提升了静叶的扩压能力。而弦长改变的同时增加了叶片前掠,阻隔了部分气流,实现了气流的重新分配,一定程度上平衡了两侧气流流量的不均匀性,从而改善了该压气机的气动稳定性。

集成压缩机用双定子磁通切换电机的设计及优化

针对轴流压缩机系统体积大、冷却难的问题,基于6/4双定子磁通切换永磁电机,提出一种新型集成压缩机用磁通切换永磁电机(FSPMM)。首先,推导了考虑转子斜极影响的齿槽转矩解析表达,建立了气体流量轨迹模型。其次,设计E型槽FSPMM和C型槽FSPMM结构并建立有限元仿真模型,对其磁密分布、反电动势、齿槽转矩、电磁转矩及波动等电磁特性进行了计算和对比分析,结果表明E型槽FSPMM的电磁性能明显优于C型槽FSPMM的电磁性能。最后,综合考虑电磁性能和流体影响,对E型槽FSPMM的转子结构进行了优化,优化后的6/4双E型槽FSPMM的转矩波动下降了15.25%,出口流速提高到113.27 m/s,适用于多级轴流压缩机系统。

可变几何楔形扩压器设计与流动分析

为了兼顾离心压气机具有高压比的同时可以拥有更宽的稳定工作裕度,以匹配楔形扩压器的高压比离心压气机为研究对象,提出一种新的扩压器轴向滑移变几何设计方案。利用经过校核的数值模拟方法开展了扩压器叶片安装角和扩压器叶片前缘轴向滑移尺寸的参数化研究,详细讨论了叶片扩压器的变角度方案和轴向滑移剪切方案对离心压气机气动性能、稳定裕度的影响规律。研究结果表明,在扩压器叶片初始设计阶段通过增大扩压器叶片安装角使压气机在小流量工况范围内运行,再通过轴向滑移式变几何扩压器机构改变叶轮与扩压器间的转静间隙,有效地将堵塞流量增大2.9%,失速流量减小7%,拓宽了离心压气机稳定运行流量范围。

某型压气机VSV机构油压驱动力试验研究

航空发动机压气机在运行过程易发生喘振现象,危及发动机寿命。为达到提高VSV机构的运行可靠性以及降低发动机能耗等目的,满足整机台架试验要求。本文搭建了某型压气机VSV机构油压驱动试验台,采集不同工况下VSV机构油压驱动力,得到了常规与极限速度下油压驱动力数据,给出了VSV机构油压驱动力变化规律。试验结果表明:常规速度下,速度变量对油压驱动力几乎没有影响,行程变化工况下到达上止点时,油压驱动力会出现阶跃现象,对压气机VSV机构工作过程中驱动力预测和规律变化以及针对发动机压气机系统能耗、效率优化研究有一定的工程意义与参考价值。

压气机叶片仿鲨鱼鳃开槽对叶栅气动性能的影响

基于鲨鱼鳃射流减阻的思想,采用数值方法,将仿鲨鱼鳃结构应用在压气机平面叶栅中。在叶片根部从压力面向吸力面开槽,采用单个进口、两个出口的开槽结构,以期在获得较大的出口射流的情况下实现对压气机叶片的减阻,达到提高叶栅气动性能的效果。在保证开槽结构的进出口宽度、出口起始位置、开槽内的隔板宽度、深度等几何参数不变的基础上,研究开槽进口起始位置、开槽高度对叶栅性能的影响。结果表明:合理的仿鲨鱼鳃开槽结构可以有效改变叶片吸力面根部角区的流动结构,抑制气流沿叶高方向的流动,从而降低流动损失;最佳方案为开槽结构位置位于48%~53%压力面弧长处,开槽高度为15%叶高,可以使压气机叶栅总压损失减小7.16%。

压气机静子上游容腔优化设计研究

从3个方向对压气机静子上游容腔进行优化设计,采用数值模拟方法对优化效果进行分析。结果表明:开槽处理会破坏流动连续性,开槽位置对流动性能的影响较大,且开槽处理方案对封严性能提升效果不明显;右端壁与左端壁两种倒圆结构在叶栅通道出口截面的总压损失系数分别下降了0.395%和0.342%;两种堆叠结构叶栅出口截面的总压损失系数分别下降2.72%和3.11%,弧形拐角的堆叠结构封严性能更优。

转静子间距对斜流压气机流动损失影响研究

斜流压气机转静子间距对整级性能有重要影响。基于非稳态流场数值模拟,计算分析不同转静子间距下叶轮、无叶段、有叶扩压段三部分流动结构及损失机理,发现随着间距的增大叶轮部分流动损失几乎不变,无叶区部分流动损失增加,有叶扩压段各个控制体的流动损失都减少。研究结果可为斜流压气机转静子匹配设计提供参考。

基于灵敏度分析的可调静叶调节机构运动精度优化

为提升高负荷多级轴流压气机静叶调节机构的运动精度,针对5级联调构型,梳理了37个对调节精度可能存在影响的参数,提出了一种基于局部灵敏度分析的参数降维预处理优化方法。通过局部灵敏度分析认识各参数对调节精度的影响规律,甄选重要参数,依靠自主优化程序与多体运动学软件联合的技术途径并采用SQP算法对机构进行优化:仅采用相对灵敏度影响最大的9个参数进行优化时,调节精度达到0.4020°;采用剔除13个绝对灵敏度最小参数后的参数进行优化时,调节精度优化达到0.2000°;而采用全部37个参数进行优化后,调节精度依然为0.2000°。结果表明:所提出的降维预处理优化方法能够在保证运动精度的同时有效减小计算规模,联合优化的方式较传统虚拟样机优化具有更高的精度。

高转速下台阶篦齿流动特性的实验与计算

对航空发动机压气机级间台阶篦齿封严进行了实验与计算研究。在不同压比(1.05~1.3)下,研究了转速(1.5~7.2kr/min)对篦齿的工作间隙变化、泄漏特性、温升特性和旋流特性的影响,并选取典型实验工况进行了数值模拟。研究表明实验结果与数值计算结果符合良好。随转速的增大,工作间隙减小,泄漏流量降低,两者最大降幅在40%左右;较小压比时流量系数微弱降低,较大压比时流量系数微弱增大。系统风阻温升随转速的增大而增大,且转速越大温升越快,最大温升为36K。另外,出口旋转盘腔同一径向位置的旋转比随转速的增大而增大,最大可达0.398;同一转速下,随出口旋转盘腔径向位置的增大,旋转比降低。

跨声压气机动静干涉效应的数值研究

采用数值方法对一轴流跨声压气机在设计点的非定常流场进行了模拟,对级内动静干涉进行了深入分析,研究了尾迹和位势作用等对动静叶表面气动负荷的影响.计算结果表明:在压气机中,上游动叶的尾迹等对静叶通道内部流动,叶片表面静压的波动,以及边界层流动损失的发生、发展和输运产生明显的影响,需要在设计中加以考虑.

总压畸变对跨声速压气机静叶端区流场结构影响研究

为了进一步研究总压畸变对静叶流场结构的影响,分析影响静叶流动稳定性的因素,采用全流道非定常数值模拟方法,对两种畸变条件下的跨声速压气机流场进行求解,重点分析静叶根部和顶部附近流场参数变化情况,角区分离在各静叶流道内的发展过程,以及畸变深度对静叶流场结构的影响。研究表明,进口总压畸变引起静叶端壁角区分离,其流场结构因静叶流道相对畸变区位置不同而不同。38.2%深度畸变造成的静叶损失高于27.2%深度畸变,并且流道内流动更复杂,存在"扰动稳定区"并且有空间旋涡环生成。静叶角区分离的主要原因是畸变流体改变了进口气流角,从而使进口冲角周向分布不均匀。

NF-6风洞马赫数控制系统研制

NF 6风洞是我国唯一一座增压连续式跨声速翼型风洞,为了提高实验雷诺数,在设计上还具有喷氮降温的功能。笔者介绍了NF 6风洞马赫数控制系统的组成、特点及运行方式,对转速控制子系统、压缩机静叶角控制子系统、二喉道栅指控制子系统等进行了较为详细的介绍。

考虑可调静叶压气机的船舶燃气轮机仿真优化

作为燃气轮机防喘措施之一,压气机可调静叶在变工况下的调节方案对燃机的运行性能具有重要影响。以某型三轴船舶燃气轮机为研究对象,建立了考虑变几何压气机的燃机系统仿真缩放(0维-1维)模型。以提高燃机运行效率为目标,通过系统仿真,得到了各个工况下低压压气机前三级可调静叶的最佳开度及整机稳态性能。仿真结果表明,与原始的可调静叶调节方案相比,采用优化方案可以提高燃机在各个工况下的经济性和稳定性,对燃机总体性能有更加积极的影响。

高负荷压气机静叶根部叶型气动性能实验研究

为研究高负荷压气机静叶根部流动状态,抽取该静叶根部叶型并模化成为平面叶栅进行吹风实验,冲角变化范围为-6°^+6°、进口马赫数变化范围为0.5~0.7。对叶栅出口截面气动参数进行了详细的测量,结果表明:非正冲角时叶展中部节距平均总压损失系数小于等于0.036,尾迹宽度和总压损失峰值随马赫数变化均不明显,正冲角时尾迹宽度和总压损失峰值急剧增加;端壁处的压力梯度随马赫数和冲角的增加而增加;0°冲角下随马赫数的增大,出口叶展中部截面二次流动能系数增加,二次流动得到加强,高能量损失区域增大并且尾迹略有变宽。