生姜植株提拉力学特性的试验研究

doi:10.13733/j.jcam.issn.2095-5553.2024.01.017

摘要/Abstract

摘要： 针对提拉式生姜收获过程中存在姜秆易断裂等问题，采用剪切、挤压、拉伸试验的方法测定生姜植株的提拉力学特性参数，寻找夹持位置、加载速度等因素对生姜植株力学特性的影响规律。试验发现:姜秆的剪切强度随着取样位置与加载速度的增大而减小；抗压强度随着取样位置的增加而增大，随着加载速度的增加略微增加后减小，姜秆的平均剪切强度与抗压强度分别为0.85 MPa、3.29 MPa。生姜块茎与姜秆结合部位的抗拉强度受到夹持位置的影响显著，呈二次函数关系，随着加载速度的增加而呈现先减少后增加的趋势，且平均抗拉强度为0.6 MPa。通过对姜秆最佳剪切与挤压位置、最佳提拉位置的寻优，确定剪切与挤压力较大的位置为结合点以上393.9 mm处、姜秆与姜块茎结合点受力最大的位置为结合点以上400 mm处。生姜植株最佳的剪切挤压位置与最佳提拉位置趋于一致，且姜秆的抗压强度远大于剪切强度。因此，选用适宜的夹紧方式及位置，可减小姜秆受到的剪切力，达到顺利拉拔生姜的效果，为提拉式生姜收获机的整体设计提供数据支撑。

关键词: 生姜植株, 姜秆, 物理特性, 力学特性

Abstract: In view of the problem of easy fracture of ginger stalk during the harvesting process of pulling ginger, shearing, squeezing and tensile tests were used to determine the mechanical parameters of ginger plant pulling, and factors such as clamping position and loading speed were found to affect ginger plants. It was found that the shear strength of ginger stalks decreased with the increase of sampling position and loading speed; the compressive strength increased with the increase of sampling position, slightly increased and then decreased with the increase of loading speed. The average shear strength and compressive strength of the culm were 0.85 MPa and 3.29 MPa, respectively. The tensile strength of the binding site of ginger tuber and ginger stalk was significantly affected by the clamping position, showing a quadratic function relationship, showing a trend of first decreasing and then increasing with the increase of loading speed, and the average tensile strength was 0.6 MPa. Through the optimization of the best shearing and pressing position and the best lifting position of ginger stalk, it was determined that the position with greater shearing and pressing force was 393.9 mm above the junction point, and the force at the junction point of ginger stalk and ginger tuber was determined. The largest position was 400mm above the junction point. The optimal shearing and pressing positions of ginger plants tended to be consistent with the optimal pulling positions, and the compressive strength of ginger stalks was much greater than the shearing strength. Therefore, choosing the appropriate clamping method and position can reduce the shear force on the ginger stalks, achieve the effect of smooth ginger pulling, and provide data support for the overall design of the pulling type ginger harvester.

Key words: ginger plant, ginger stalk, physical characteristics, mechanical property

中图分类号:

S223.5

张鹏程, 贾松涛, 王方艳, 黄新平. 生姜植株提拉力学特性的试验研究[J]. 中国农机化学报, 2024, 45(1): 117-121.

Zhang Pengcheng, Jia Songtao, Wang Fangyan, Huang Xinping. Experimental study on mechanical properties of ginger plants[J]. Journal of Chinese Agricultural Mechanization, 2024, 45(1): 117-121.

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