对辊式叶林杜仲脱叶剥皮机设计与试验

doi:10.11707/j.1001-7488.LYKX20250055

摘要/Abstract

摘要：

目的: 设计开发一款对辊式叶林杜仲脱叶剥皮机，以实现连续化叶林杜仲细枝木脱叶剥皮作业，解决叶林杜仲规模化采收过程中机械化水平低的难题。方法: 在测定目标物料基本特性参数的基础上，以整机工作性能要求为主要准则，利用EDEM软件进行仿真模拟和台架试验，得出拉削对辊的螺距、间距和转速比的最佳切割效果组合参数，确定对辊的数量与合理的传动方式；分析脱叶锤片受力情况，确定锤片机构结构尺寸与排列方式，完成装备关键零部件的设计；选择脱叶和剥皮进料辊转速、锤片辊转速等作为试验因素，以脱叶率、剥皮率和生产效率为试验指标，通过田间试验对整机工作性能进行评价。结果: 1）拉削对辊机构对杜仲树皮的切割效果随着对辊间距增大而降低，但与螺距和转速比无相关性；最佳切割效果组合参数为：拉削辊直径150 mm、长度1250 mm、螺距2.5 mm、间距10 mm、转速比1、对辊数量2组、转速400 r·min^–1。2）锤片机构采用定距、偶数、均布的方式排列；锤片长130 mm、宽50 mm、厚4 mm、锤片间距15 mm、数量40，对辊数量2组、转速1200 r·min^–1时，效果最佳。3）田间试验结果显示，基于设计参数研制的杜仲脱叶剥皮机对当年生采收1天内、含水率58%~70%的杜仲细枝木剥净率最高，脱叶率达100%，剥皮率为78%，生产效率为64%。结论: 对辊式叶林杜仲脱叶剥皮机试验的各项指标均达到设计目标，为叶林杜仲机械化采收装备的研发提供了一种参考方案。

关键词: 叶林杜仲, 对辊式, 锤片, 脱叶机构, 剥皮机构

Abstract:

Objective: In this study, a roller-type leaf-stripping and bark-peeling machine was designed and developed to achieve continuous leaf-stripping and bark-peeling operations for annual Eucommia ulmoides twigs during harvest, in order to address the low mechanization level in the large-scale harvesting process of E. ulmoides leaf-used forests. Method: Based on the determined characteristic parameters of the material and the performance criteria of the machine, EDEM software was employed for simulation analyses and bench tests to determine the optimal configuration of parameters, including the pitch, spacing, and speed ratio of the dual-roller cutting mechanism. Besides, the most appropriate number of rollers and a reasonable transmission mode were determined to ensure that the machine’s design meeting both performance specifications and operational efficiency standards. The force situation of the hammer blade used for defoliation was analyzed to determine the structural dimensions and arrangement of the hammer blade mechanism, and the design of key components of the equipment was completed. The feed roller speed and hammer blade roller speed for defoliation and peeling were selected as experimental factors, and the defoliation rate, peeling rate, and production efficiency were used as experimental indicators, to evaluate the overall performance of the machine. Result: 1) The cutting efficiency of the dual-roller mechanism on E. ulmoides bark decreased as the roller spacing increased, but was not significantly correlated with either the pitch or the speed ratio. The optimal parameter set comprised the cutting roller diameter of 150 mm, length of 1250 mm, pitch of 2.5 mm, the dual-roller spacing of 10 mm, the speed ratio of 1, two pairs of dual-rollers, and the rotational speed of 400 r·min^–1. 2) The hammer blade mechanism was configured in a fixed-distance, even number, and uniformly spaced arrangement. When hammer blades were 130 mm in length, 50 mm in width, and 4 mm in thickness, with a spacing of 15 mm between each hammer blade, a total of 40 hammers, two pairs of dual-rollers, rotating at a speed of 1 200 r·min^–1, the optimal defoliation effect could be achieved. 3) Field trial results indicated that the machine based on the design parameters exhibited the highest stripping efficiency for E. ulmoides twigs harvested in the first day of the annual growth cycle, with a moisture content ranging from 58%?70%. The defoliation rate achieved 100%, peeling rate achieved 78%, and the production efficiency reached 64%. Conclusion: The roller-type leaf-stripping and bark-peeling machine has achieved all the main design objectives, and this design may provide a reference solution for the development of mechanized harvesting equipment for E. ulmoides leaf-used forests.

Key words: leaf-used forest of Eucommia ulmoides, roller-pair type, hammer flake, defoliating mechanism, peeling mechanism

中图分类号:

S776.31

谷芳,宋明洋,樊扬,冯腾辉,朱琳,朱铭强. 对辊式叶林杜仲脱叶剥皮机设计与试验[J]. 林业科学, 2025, 61(10): 201-210.

Fang Gu,Mingyang Song,Yang Fan,Tenghui Feng,Lin Zhu,Mingqiang Zhu. Design and Performance Test of a Roller-Type Machine for Leaf Stripping and Peeling of Eucommia ulmoides in Leaf-Used Forests[J]. Scientia Silvae Sinicae, 2025, 61(10): 201-210.

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参数Parameters	均值±标准差Value±SD
树皮密度Bark density/ (kg·m^–3)	932.02±9.32
弹性模量Elastic modulus/MPa	41.0±0.41
剪切模量Shear modulus/MPa	13.9±0.14
泊松比Poisson’s ratio	0.34±0.004
叶柄剪切力Petiole shear force/N	35.35±0.35

组别 Group	对辊螺距 Roller pitch of the pair of rolls (A)/mm	对辊间距 Spacing between the pair of rolls (B) /mm	转速比 Speed ratio (C)	键破坏数量 Number of broken bonds
1	1.5	7	3	4779
2	1.5	7	1	2453
3	1.5	4	2	20651
4	1.5	10	2	446
5	2.5	4	1	5837
6	2.5	10	1	313
7	2.5	4	3	11239
8	2.5	10	3	391
9	2.5	7	2	1042
10	3.5	7	1	2637
11	3.5	7	3	3207
12	3.5	4	2	17561
13	3.5	10	2	532

来源 Source	自由度 df	F	P
模型 Model	3	6.04	0.0154
对辊螺距 Paired roller pitch	1	0.01179	0.7392
对辊间距 Distance between rollers	1	17.57	0.0023
转速比 Rotational speed ratio	1	0.4289	0.5289
残差 Residual	9	—	—
总和 Sum total	12	—	—

工作条件 Working conditions	数值 Value
电压频率 Voltage frequency/Hz	380/50
脱叶功率 Defoliation frequency/kW	3.7
剥皮功率 Peeling frequency/kW	3.7
传动功率 Transmission frequency/kW	0.75

组别Group	树皮质量 Weight of bark/kg		剥皮率 Bark removal rate (%)		生产效率 Production efficiency (%)		脱叶率 Leaves removal rate (%)
组别Group	W	w'	P	x±SD	τ	x±SD	P'
1	1.41	1.05	74	67.4±7.0	56	54.6±4.4	100
	1.72	1.22	71		53
	1.45	0.80	55		55
	2.02	1.33	66		53
	2.21	1.57	71		56

2	1.81	1.36	75	74.2±4.79	61	59.6+±9.0	100
	1.75	1.32	75		62
	2.07	1.51	73		60
	2.35	1.74	74		58
	1.75	1.29	74		57

3	2.58	2.04	79	78.8±2.1	63	64.2±2.8	100
	1.66	1.24	75		65
	1.87	1.50	80		64
	2.33	1.89	81		65
	1.88	1.49	79		64

4	2.57	1.95	76	76.4±1.7	61	61.6±1.1	100
	2.78	2.20	79		63
	2.26	1.72	76		62
	2.13	1.64	77		60
	1.55	1.15	74		62

5	2.74	1.94	71	74.2±4.0	59	59.6±1.1	100
	3.21	2.44	76		58
	2.85	2.08	73		60
	1.79	1.36	76		60
	2.12	1.59	75		61