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工程设计学报
工程设计学报  2026, Vol. 33 Issue (2): 223-233    DOI: 10.3785/j.issn.1006-754X.2026.05.193
优化设计     
叶片尾缘结构对轴流风机性能的影响研究
张浪(),李科军(),邓旻涯,王波,李兴华
中南林业科技大学 机械与智能制造学院,湖南 长沙 410004
Study on influence of blade trailing edge structure on performance of axial flow fans
Lang ZHANG(),Kejun LI(),Minya DENG,Bo WANG,Xinghua LI
School of Mechanical and Intelligent Manufacturing, Central South University of Forestry & Technology, Changsha 410004, China
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摘要:

针对轴流风机叶片尾缘轮廓线内切圆半径收敛至零所引起的铸造工艺问题,对现有叶片尾缘加厚结构进行了研究,并提出了一种新型的叶片尾缘倒圆结构。通过建立轴流风机的数值仿真模型,使用计算流体力学方法对采用不同叶片尾缘结构时风机的风量、全压、叶轮功率、全压效率和噪声进行了仿真分析。结果表明:采用不同叶片尾缘结构时风机的最大风量均随尾缘厚度的增大而逐渐减小;尾缘厚度每增大0.5 mm,采用加厚结构和倒圆结构时风机的最大风量分别约降低0.72%和0.68%;在设计风量下,尾缘厚度每增大0.5 mm,采用加厚结构和倒圆结构时风机的叶轮功率分别约降低1.92%和1.87%,全压分别约降低3.04%和2.84%,全压效率分别约降低0.47%和0.62%。当加厚结构的厚度l=2.5 mm时,靠近叶轮处的噪声最小,为105.41 dB,较l=0 mm时减小了0.79 dB;当倒圆结构的圆角直径D=3.0 mm时,靠近叶轮处的噪声最小,为104.91 dB,较D=0 mm时减小了1.29 dB。通过量化尾缘厚度变化对轴流风机性能的影响,解决了叶片的铸造工艺问题,为叶片尾缘的结构设计及气动性能优化提供了参考。
关键词: 轴流风机叶片尾缘结构风量全压全压效率叶轮功率声学性能    
Abstract:

To address the casting process problem caused by the convergence of the inscribed circle radius of the axial flow fan blade trailing edge contour to zero, the existing blade trailing edge thickening structure is researched, and a new type of blade trailing edge rounding structure is proposed. Through establishing a numerical simulation model of the axial flow fan, the air flow rate, total pressure, impeller power, total pressure efficiency and noise of the fans with different trailing edge structures were analyzed by the computational fluid dynamics method. The results showed that the maximum air flow rate of the fans with different trailing edge structures gradually decreased with the increase of trailing edge thickness. For every 0.5 mm increase in trailing edge thickness, the maximum air flow rate of the fans with thickening structure and rounding structure was reduced by 0.72% and 0.68%, respectively. Under the designed air flow rate, for every 0.5 mm increase in trailing edge thickness, the impeller power of the fans with thickening structure and rounding structure was reduced by 1.92% and 1.87%, the total pressure was decreased by 3.04% and 2.84%, and the total pressure efficiency was reduced by 0.47% and 0.62%. When the thickness l of the thickening structure was 2.5 mm, the noise near the impeller was the minimum, reaching 105.41 dB, which was 0.79 dB lower than that at l=0 mm. When the fillet diameter D of the rounding structure was 3.0 mm, the noise near the impeller was the minimum, reaching 104.91 dB, which was 1.29 dB lower than that at D=0 mm. By quantifying the impact of trailing edge thickness variations on the performance of axial flow fans, the casting process problem of the blade is solved, which provides a reference for the structural design of the blade trailing edge and the optimization of its aerodynamic performance.
Key words: axial flow fan    blade trailing edge structure    air flow rate    total pressure    total pressure efficiency    impeller power    acoustic performance
收稿日期: 2025-07-13 出版日期: 2026-04-28
CLC:  TH 432.1  
基金资助: 湖南省自然科学基金资助项目(2022JJ31015)
通讯作者: 李科军     E-mail: zl15770551720@163.com;likejuncsu@126.com
作者简介: 张 浪(2001—),男,硕士生,从事流体力学及流体机械设计研究,E-mail: zl15770551720@163.com
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引用本文:

张浪,李科军,邓旻涯,王波,李兴华. 叶片尾缘结构对轴流风机性能的影响研究[J]. 工程设计学报, 2026, 33(2): 223-233.

Lang ZHANG,Kejun LI,Minya DENG,Bo WANG,Xinghua LI. Study on influence of blade trailing edge structure on performance of axial flow fans[J]. Chinese Journal of Engineering Design, 2026, 33(2): 223-233.

链接本文:

https://www.zjujournals.com/gcsjxb/CN/10.3785/j.issn.1006-754X.2026.05.193        https://www.zjujournals.com/gcsjxb/CN/Y2026/V33/I2/223

图1  轴流风机叶片结构
图2  轴流风机物理模型
图3  轴流风机网格模型
图4  网格无关性验证结果
参数数值参数数值
风量/(m3/s)14叶轮直径/mm900
电机功率/kW15叶轮叶片数10
安装角/(°)50导叶数9
叶顶间隙/mm2轮毂比0.564
表1  轴流风机的主要参数
图5  轴流风机气动性能
图6  叶片尾缘结构示意图
图7  尾缘加厚结构对轴流风机气动性能的影响
图8  不同厚度 l 下50%叶高处的全压分布云图
图9  不同厚度 l 下叶尖处的静压脉动曲线
图10  不同厚度 l 下叶尖处的噪声频谱图
图11  尾缘倒圆结构对轴流风机气动性能的影响
图12  不同圆角直径 D 下50%叶高处的轴向速度分布云图
图13  不同圆角直径 D 下叶尖处的静压脉动曲线
图14  不同圆角直径 D 下叶尖处的噪声频谱图
图15  轴流风机的最大风量对比
图16  轴流风机的叶轮扭矩对比( q=11.5 m3/s)
尾缘厚度/mm叶轮功率/kW
采用加厚结构采用倒圆结构
011.3211.32
1.010.9111.16
1.510.6910.86
2.010.5310.69
2.510.3510.45
3.09.9310.01
表2  轴流风机的叶轮功率对比( q=11.5 m3/s)
图17  轴流风机的全压对比( q=11.5 m3/s)
图18  轴流风机叶轮区域的涡量分布对比( q=11.5 m3/s)
图19  轴流风机的全压效率对比( q=11.5 m3/s)
图20  尾缘厚度为1.5 mm时叶尖处的静压脉动曲线对比( q=11.5 m3/s)
图21  尾缘厚度为1.5 mm时叶尖处的噪声频谱图对比(q=11.5 m3/s)
  
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