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本文选择RANS方程和RNG k-ε湍流模型,采用有限体积法,在假定流动定常的前提下对离心泵中叶片与蜗舌不同相对位置时的流场进行数值模拟,总结分析了各性能参数的计算误差在不同的相对位置时的变化规律.通过叶片与蜗舌不同相对位置时对各性能参数计算误差的均方差进行比较,认为存在一个合适的相对位置使得对各性能参数的总体预测精度保持最高,为数值方法分析离心泵的性能提供了指导. 相似文献
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本文使用5孔探针,在近失速工况下,对3种不同叶顶间隙时的后置蜗壳斜流叶轮进出口流场三维速度分布进行了测量,并将实验结果与非失速小流量的出口流场做了比较。 相似文献
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本文采用计算流体动力学和声类比相结合的混合方法对空调用离心风机进行流场以及声场的计算,同时进行风机风量和噪声的实验测量,验证所采用的数值计算模型和计算方法的有效性.针对原型非常规蜗壳,提取蜗壳中间截面型线进行直蜗舌的蜗壳设计,在此基础上设计了三种倾斜蜗舌的蜗壳.根据数值计算结果,对最优倾斜蜗舌进行了实验验证。经实验测试,风机在各个工况点风量均有提升,在最大风量点风量提升6.0%,噪声降低1.4 dB(A).数值分析风机内部流动特征及噪声特性,发现在蜗舌附近流动区域内湍流强度和涡量明显减小,在叶片通过频率处声功率谱密度以及噪声峰值明显下降,这也表明风机的旋转噪声得到了有效控制。 相似文献
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不稳定流动是高速离心压缩机内部流动的本质特征,其诱发机制往往受到关键结构参数与边界处流动条件的影响.本文以带有无叶扩压器的离心压缩机为研究对象,基于线性的全局稳定性理论,同时考虑涡黏性与分子黏性的作用,建立了基于无叶扩压器r-θ平面的二维稳定性分析方法,获得了流动失稳的直接全局模态;然后基于伴随方法获得了对应最不稳定特征值的伴随全局模态,结合直接与伴随模态构建了流场特征值的结构敏感性。最后考虑了射流-尾流流动结构,以及蜗壳非对称几何结构的影响,分别对周向非均匀入流/出流条件下的无叶扩压器流动进行了稳定性与敏感性分析。分析结果表明机匣侧出口回流对无叶扩压器全局稳定性具有关键作用;在无蜗壳时,射流-尾流结构对于全局稳定性的影响主要体现在失速团个数,而对失稳机理的影响较小;蜗壳的非对称结构导致流场重新分布,在距离蜗舌顺时针90°~135°位置出口壁面回流与入口回流相互作用,是诱发失稳扰动产生的主要因素。 相似文献
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The most cited analytical technique for designing turbine volutes is to assume the throughflow is free from torque, although for this assumption to hold, the volute walls must lie near what would be streamlines in an unbounded free vortex-plus-sink flow. The single tangential inlet design, with inlet offset decreased and diameter increased to attain the weak exit swirl required by high specific speed turbines, deviates from such a shape, and the volute’s internal geometry is no longer torque-free. It is desired to know the actual time-averaged flow leaving such a volute, so that a rotor can be designed to compliment it.For two existing single tangential inlet volutes, time-averaged radial and tangential velocity and static pressure measurements of exit flow have been obtained on a cylindrical cut plane through the radial-inflow section using a three-port yawmeter in air. The Reynolds numbers based on inlet pipe mean conditions, around 105, are well into the fully-turbulent regime and on the order of comparable water turbines.A comprehensive map of time-averaged exit flow of both volutes is presented. The integrated values of gross angular momentum flux change and total pressure loss coefficient are tabulated. Circumferential variation of flowrate and swirl strength highlight unexpected differences in outlet flow between the two volute designs. Results are presented alongside corresponding numerical results from the commercial package Fluent (Fluent, Inc., Lebanon, NH, USA) using Reynolds stress, k-ω, and inviscid flow models.In both volutes, measured gross exit angular momentum flux was more than 1.7 times what the zero-torque assumption would predict when blindly applied to the volute as a whole. This discrepancy is attributed to significant turning near the volute’s inlet region leading to an updated view of what an appropriate control volume is when applying the zero-torque assumption. Additionally, variation of both radial and tangential velocity in both the circumferential and axial directions on the order of 15% of the mean value reveal that volute swirl characterization by a single measurement would have a significant associated uncertainty. 相似文献