邢浩男, 马少春, 莫建霖, 曾伯胜, 梁文鹏, 李伟庆, 王风磊, 白静, 丁征亮. 甘蔗收割机排杂风机叶轮结构参数优化与试验[J]. 农业工程学报, 2021, 37(12): 12-19. DOI: 10.11975/j.issn.1002-6819.2021.12.002
    引用本文: 邢浩男, 马少春, 莫建霖, 曾伯胜, 梁文鹏, 李伟庆, 王风磊, 白静, 丁征亮. 甘蔗收割机排杂风机叶轮结构参数优化与试验[J]. 农业工程学报, 2021, 37(12): 12-19. DOI: 10.11975/j.issn.1002-6819.2021.12.002
    Xing Haonan, Ma Shaochun, Mo Jianlin, Zeng Bosheng, Liang Wenpeng, Li Weiqing, Wang Fenglei, Bai Jing, Ding Zhengliang. Optimization and experiment of parameters for the impeller structure of extractor in a sugarcane chopper harvester[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2021, 37(12): 12-19. DOI: 10.11975/j.issn.1002-6819.2021.12.002
    Citation: Xing Haonan, Ma Shaochun, Mo Jianlin, Zeng Bosheng, Liang Wenpeng, Li Weiqing, Wang Fenglei, Bai Jing, Ding Zhengliang. Optimization and experiment of parameters for the impeller structure of extractor in a sugarcane chopper harvester[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2021, 37(12): 12-19. DOI: 10.11975/j.issn.1002-6819.2021.12.002

    甘蔗收割机排杂风机叶轮结构参数优化与试验

    Optimization and experiment of parameters for the impeller structure of extractor in a sugarcane chopper harvester

    • 摘要: 切断式甘蔗收割机排杂风机的作业质量对甘蔗的含杂率有重要影响。为提高排杂风机叶轮的性能,该研究首先针对排杂风机建立了计算流体力学模型,以叶片安装角(β)、叶片数(N)、间隙占比(G)为因素,以风机转速为1 650 r/min时的空载风速为指标,设计了三因素三水平的Box-Behnken仿真试验,并对叶轮参数进行优化。结果表明:在叶片数为3~5、安装角为20°~30°、间隙占比为55%~70%的范围内,G、G2、N2、G、N2×G对风机的空载风速影响极显著(P<0.01),N和N×G对空载风速影响显著(P<0.05)。优化得到叶轮最佳结构参数为:叶片数为4、安装角为30°、间隙占比为55%。风速仿真值与测量值的最大误差为5.24%,平均误差为4.29%,仿真结果具有较高的准确性。以优化参数进行的田间试验结果表明,收获长势差的甘蔗时含杂率最多降低2.4个百分点,损失率最多上升0.85个百分点。本研究提高了风机在复杂田间情况下的排杂性能。

       

      Abstract: Abstract: An impeller is one of the most important core components for the extractor in a sugarcane chopper harvester. Aerodynamic characteristics of impeller mainly dominates the cleaning performance of an extractor. Therefore, this study aims to optimize the structural parameters of impeller for a better performance using numerical simulation on CFD platform and response surface method (RSM). A realizable K - ε turbulence model was selected to calculate the internal flow field of an extractor in CFD simulation. A verification test showed that the maximum error of simulated value was 5.24%, and the average error was 4.29%, indicating a higher accuracy of model. A Box-Behnken design was utilized for the response surface test. Specifically, the installation angle (β), the number of blades (N), and gap ratio (G) were taken as the factors, whereas, the wind speed (v) of an extractor under no-load condition was taken as the evaluation index. Additionally, the impurity rate was used as the evaluation index in the pretest to determine the range of gap ratio. The pretest results showed that there was no significant difference in the impurity rate of impeller with four kinds of G values under the same wind speed. It infers that the G value posed nothing effect on the relationship between no-load wind speed and impurity rate. Subsequently, the level of response surface test was determined after the pretest. The analysis of variance show that N2, β, β2, G and N2×G presented extremely significant effects on the evaluation index, while N and N×G significant influence. An investigation was made to explore the variation in the attack angle in the main work area of a blade and the vortex distribution at the root, in order to reveal the influence mechanism of each factor on the evaluation index. It was found that the v increased with the increasing β, but when β = 30°, the performance of blade tip was reduced with the upward trend of v. Furthermore, the vortex caused the flow field near the impeller to deteriorate, when N and G were at the lowest level. An optimal combination of structural parameters in the impeller were achieved, where N= 4, β = 30° and G = 55%. Two kinds of sugarcane from different sites were used in field experiment, thereby to evaluate the cleaning effect of an extractor on the sugarcane with high impurity content. The sugarcane on the site I was growing well, and the sugarcane on the site II was short while containing more impurities. The field test showed that the impurity rate was reduced by 2.34, 2.2, and 2.4 percentage points, when the driving speed was 2.5, 3.0, and 3.5 km/h, respectively, indicating a better performance under the optimized impeller on the site II. The optimized extractor also increased the loss rate. The loss rate increased by 1.01 and 0.85 percentage points, but the decrease in the impurity rate was greater than the increase in the loss rate, when harvesting the sugarcane in the normal and under growth state in the field.

       

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