旋转包络梳脱式烟叶采收机构设计与试验

doi:10.12133/j.smartag.SA202501020

Smart Agriculture

• •

旋转包络梳脱式烟叶采收机构设计与试验

王潇涵¹(), 冉云亮², 葛朝², 郭婷⁴, 刘艺豪¹, 陈度³(), 王书茂¹

^1. 中国农业大学工学院，北京 100083，中国
^2. 河南农先锋科技股份有限公司，河南郑州 450002，中国
^3. 现代农业装备优化设计北京市重点实验室，北京 100083，中国
^4. 湖南省烟草公司郴州市公司，湖南郴州，423000，中国

收稿日期:2025-01-18 出版日期:2025-04-24
基金项目:
National Key Research and Development Program Project(NK2024YFD2000503); The Fundamental Research Funds for the Central Universities(2024AC047); Research and Development of Intelligent Transportation and Cigarette Loading Machinery for Cigarette Holders in Intensive Baking Production Scenarios(202405410711093)
作者简介:
王潇涵，硕士生，研究方向为烟叶机械化采收。E-mail：wxh010408@126.com
通信作者:
陈度，博士，教授级高级工程师，研究方向为农机装备智能测控技术。E-mail：tchendu@cau.edu.cn

Design and Test of Rotating Envelope Comb Stripping Tobacco Picking Mechanism

WANG Xiaohan¹(), RAN Yunliang², GE Chao², GUO Ting⁴, LIU Yihao¹, CHEN Du³(), WANG Shumao¹

^1. College of Engineering, China Agriculture University, Beijing 100083, China
^2. Henan Agriculture Pioneer Technology Co. , Ltd. , Zhengzhou 450002, China
^3. Beijing Key Laboratory for Optimized Design of Modern Agricultural Equipment, Beijing 100083, China
^4. Chenzhou Branch of Hunan Tobacco Company, Chenzhou 423000, China

Received:2025-01-18 Online:2025-04-24
About author:
WANG Xiaohan, E-mail: wxh010408@126.com
Corresponding author:
CHEN Du, E-mail: tchendu@cau.edu.cn

摘要/Abstract

摘要：

【目的/意义】 针对烟叶机械化采收过程中叶片损伤大、漏采率高等问题，设计了一种旋转包络梳脱式烟叶采收机构，该机构利用旋转包络机构实现植株和烟叶的套取，进而利用连杆结构的惯性作用力实现分层脱叶，从而实现成熟烟叶的连续、分层采收。 【方法】 首先根据烟株的形态特征与烟叶生长物理特性，设计了上下轮盘式烟杆包络机构，进而采用自上而下惯性击打的方式梳脱分离烟叶，与传统的旋转拍打式采收机构相比，该机构采用包络烟杆击打烟叶根部的采收方式，避免了与烟叶叶片的直接碰撞，从而降低采收损伤。然后，对击打梳脱分离过程进行力学分析，并通过改进粒子群算法对传动机构参数进行了优化与验证，随后，对采收机构脱分离烟叶的过程进行了有限元仿真分析以优化轮盘结构参数并通过动力学仿真分析确定了采收机构的作业参数范围，最后，对不同转速下的采收效果进行田间试验。 【结果和讨论】 经有限元仿真分析确定了轮盘结构参数中主要影响采收效果的参数为采摘杆直径，确定采摘杆直径为15 mm，包络圆直径为70 mm，材料为铝合金。经动力学仿真分析确定了采收机构梳脱速度应不大于3.0 m/s，对应转速应在120~210 r/min范围内。最终田间试验结果表明，采收机构的漏采率小于10%，破损率小于7%，能够有效减少烟叶漏采率和破损率。 【结论】 研究结果可为自动化烟叶采收机械的设计与集成提供支撑。

关键词: 烟叶收获, 梳脱采收, 收获损失, 机构设计

Abstract:

[Objective] China is the world's large tobacco producer, where tobacco significantly contributes to the national economy. Among all production stages, leaf picking process requires the most labor. Currently, tobacco picking in China remains predominantly manual, characterized by low mechanization, high labor demand, constrained picking period, and intensive labor intensity requirement. As agricultural modernization progresses, mechanized tobacco picking has become increasingly essential. However, existing foreign tobacco harvesters are oversized and cause substantial leaf damage, making them unsuitable for domestic conditions. A rotating envelope picking mechanism designed is proposed to minimize leaf damage and loss during picking. [Methods] A tobacco plant model was developed based on morphological characteristics and assessed mechanical properties of tobacco leaves using a digital push-pull force gauge to measure tensile and bending characteristics. Force measurements for leaf separation in various directions revealed minimal force requirements when separating leaves from top to bottom. Based on these findings, a rotating envelope comb-type picking mechanism was designed, featuring both a transmission mechanism and a picking wheel. During operation, the picking wheel rotates around the tobacco stem, employing inertial combing from top to bottom for efficient leaf separation. Analysis of interactions between the picking mechanism and tobacco leaves identified combing speed as the parameter with greatest impact on picking efficiency. The mechanism's structural parameters affecting the picking wheel's movement trajectory were examined, and an improved particle swarm optimization algorithm was applied using MATLAB to refine these parameters. Additionally, Abaqus finite element simulation software was utilized to optimize the wheel structure's mechanical combing process. Dynamic simulation tests using Adams software modeled the mechanism's process of enveloping the tobacco stem and separating leaves, validating suction efficiency and determining optimal envelope range and speed parameters at various traveling speeds. To evaluate the picking effect and effectiveness of the tobacco leaf picking mechanism designed in this study, a field experiment was conducted in Sanxiang town, Yiyang county, Henan province. The performance of the picking mechanism was analyzed based on two critical evaluation criteria: the rate of tobacco leaf damage and the leakage rate. [Results and Discussions] By optimizing the mechanism's structural parameters using MATLAB, horizontal movement was reduced by 50.66%, and the movement trajectory was aligned vertically with the tobacco leaves, significantly reducing the risk of collision during the picking process. Finite element analysis identified the diameter of the picking rod as the key structural parameter influencing picking performance. Following extensive simulations, the optimal picking rod diameter was determined to be 15 mm, offering an ideal balance between structural strength and functional performance. The optimal envelope circle diameter for the mechanism was established at 70 mm. Aluminum alloy was selected as the material for the picking rod due to its lightweight nature, high strength-to-weight ratio, and excellent corrosion resistance. Dynamics analysis further revealed that the combing speed should not exceed 2.5 m/s to minimize leaf damage. The ideal rotational speed range for the picking mechanism was determined to be between 120 and 210 r/min, balancing operational efficiency with leaf preservation. These findings provide crucial guidance for refining the design and enhancing the practical performance of the picking mechanism. Field tests confirmed that the mechanism significantly improved operational performance, achieving a leakage rate below 7% and a damage rate below 10%, meeting the requirements for efficient tobacco picking. It was observed that excessive leaf leakage primarily occurred when leaves were steeply inclined, which hindered effective stem envelopment by the picking mechanism. Consequently, the mechanism proved particularly effective for picking centrally positioned leaves, while drooping leaves resulted in higher leakage and damage rates. The primary cause of leaf damage was found to be mechanical contact between the picking mechanism and the leaves during operation. Notably, while increasing striking speed reduced leakage, it simultaneously led to a higher damage rate. Compared to existing picking mechanism, this newly developed mechanism was more compact and supports layered leaf picking, making it especially well-suited for integration into small- and medium-sized picking machinery. [Conclusions] This study presents an effective and practical solution for tobacco leaf picking mechanization, specifically addressing the critical challenges of leaf damage and leakage. The proposed solution not only improves picking quality but also features a significantly simplified mechanical structure. By combining innovative technology with optimized design, this approach minimizes impact on delicate leaves, reduces leakage, and ensures higher yields with minimal human intervention. Analysis and testing demonstrate this mechanized solution's potential to significantly reduce production losses, offering both economic and operational benefits for the tobacco industry.

Key words: tobacco harvest, combing harvest, harvest loss, mechanism design

中图分类号:

S225.99

王潇涵, 冉云亮, 葛朝, 郭婷, 刘艺豪, 陈度, 王书茂. 旋转包络梳脱式烟叶采收机构设计与试验[J]. 智慧农业(中英文), doi: 10.12133/j.smartag.SA202501020.

WANG Xiaohan, RAN Yunliang, GE Chao, GUO Ting, LIU Yihao, CHEN Du, WANG Shumao. Design and Test of Rotating Envelope Comb Stripping Tobacco Picking Mechanism[J]. Smart Agriculture, doi: 10.12133/j.smartag.SA202501020.

图/表 28

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图9

图10

表3

图11

图12

表4

表5

图13

表6

采收轮盘参数的正交试验结果与极差分析

序号	采收杆直径A/mm	包络圆直径B/mm	材料密度 C/（kg/mm³）	空列D	最大应力/MPa
最优组合	$A 1 B 1 C 1$			—	—
1	15	70	2.74e^-6	1	0.457
2	15	80	4.43e^-6	2	0.473
3	15	90	8.96e^-6	3	0.464
4	10	70	4.43e^-6	3	0.505
5	10	80	8.96e^-6	1	0.529
6	10	90	2.74e^-6	2	0.511
7	5	70	8.96e^-6	2	0.638
8	5	80	2.74e^-6	3	0.612
9	5	90	4.43e^-6	1	0.639
$k 1 j$ 平均响应值	0.465	0.533	0.527	—	—
$k 2 j$ 平均响应值	0.515	0.538	0.539	—	—
$k 3 j$ 平均响应值	0.630	0.538	0.544	—	—
$R j$ 极差	0.165	0.005	0.017	—	—
因子主次	1	3	2	—	—

表6

表7

图14

图15

图16

图 17

图18

图19

表8

图 20

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品种	高度/m			烟杆直径/mm			叶片数/片			最低叶片高度/mm			冠层直径/m
品种	范围	平均值	标准差	范围	平均值	标准差	范围	平均值	标准差	范围	平均值	标准差	范围	平均值	标准差
平均值	1.13			35.6			18			174			1.1
云烟87（福建）	1.00~1.20	1.08	0.08	30.1~36.0	32.8	1.87	16~18	17	1	110~180	159	24.70	0.9~1.2	1.1	0.09
云烟87（云南）	1.20~1.30	1.27	0.05	30.4~39.2	35.9	1.81	18~20	19	1.86	150~200	177	18.63	0.9~1.2	1.1	0.14
K326（云南）	1.00~1.10	1.08	0.03	35.1~45.4	39.9	2.08	18~22	20	1.67	180~230	198	18.34	0.9~1.2	1.1	0.10

品种	叶长/mm			叶宽/mm			叶柄直径/mm						叶倾角/°			叶厚/mm			叶间距/mm
	叶长/mm			叶宽/mm			横向			纵向			叶倾角/°			叶厚/mm			叶间距/mm
	范围	平均值	标准差	范围	平均值	标准差	范围	平均值	标准差	范围	平均值	标准差	范围	平均值	标准差	范围	平均值	标准差	范围	平均值	标准差
平均值	749			269			22.2			13.7			44.8			0.4			50
云烟87 （福建）	690~810	755	55.13	220~380	292	39.02	18.9~23.5	21.1	1.83	13.3~15.0	13.6	1.59	25~60	44.7	12.54	0.2~0.5	0.3	0.12	30~60	51	12.24
云烟87 （云南）	620~890	733	59.54	180~360	272	40.91	18.7~26.8	23.6	1.91	11.7~17.1	14.2	1.17	25~60	45.4	11.61	0.3~0.6	0.5	0.11	40~80	55	10.73
K326 （云南）	590~920	758	34.68	210~400	276	40.86	18.5~26.8	22.7	1.31	11~17.3	13.2	0.73	30~55	44.4	12.02	0.3~0.8	0.5	0.11	20~70	45	13.28

参数	l₁/mm	l₂/mm	l₃/mm	l₄/mm	l₅/mm	θ₀/°
优化前	55	150	150	150	160	90
优化后	39.72	170.26	153.18	163.92	119.09	89.75
优化后取整	40	170	150	160	120	90

材料	密度/（kg/mm³）	杨氏模量/MPa	泊松比
烟叶	8.50e^-7	29.78	0.30
烟杆	1.60e^-6	120.00	0.33
铝合金	2.74e^-6	7.17e⁴	0.33
钛合金	4.43e^-6	1.05e⁵	0.33
铜合金	8.96e^-6	1.1e⁵	0.33

方差源	平方和	自由度	均方	F值	P值
模型	0.043 4	6	0.007 2	35.920 0	0.027 3*
A	0.042 9	2	0.021 5	106.300 0	0.009 3**
B	0.000 0	2	0.000 0	0.108 1	0.902 4
C	0.000 5	2	0.000 2	1.150 0	0.465 3
误差	0.000 4	2	0.000 2	—	—
总和	0.043 8	8	—	—	—

旋转包络梳脱式烟叶采收机构设计与试验

Design and Test of Rotating Envelope Comb Stripping Tobacco Picking Mechanism

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序号	转速/ （r/min）	采收叶片总数/片	漏采叶片数量/片	破损叶片数量/片	漏采率/%	破损率/%
1	180	58	1	3	1.72	5.26
2	180	64	4	5	6.25	8.33
3	180	46	4	3	8.70	7.14
总计	180	168	7	11	4.17	6.83
4	150	35	2	2	5.71	6.06
5	150	29	2	2	6.90	7.41
6	150	36	1	2	2.78	5.71
总计	150	100	5	6	5.00	6.31
7	120	25	3	2	12.00	9.09
8	120	23	1	1	4.34	4.55
9	120	28	2	1	7.14	3.85
总计	120	76	6	4	7.89	5.71
平均值		344	18	21	5.23	6.44