大树土球原位捆绑装置及捆绑策略的设计与试验OA
Design and Testing of an in-situ Bundling Device and Bundling Strategy for Large Tree Earthballs
[目的]设计一种大树土球原位捆绑装置及其捆绑策略,解决大树移植过程中大树土球捆绑依靠人工、效率低且无机可用的问题.[方法]通过分析手工捆绑轨迹,模块化设计定位抱紧机构,该机构通过 10个紧定螺栓径向调节,适配胸径 150~220 mm大树,保障与树干同轴心.采用齿轮齿环啮合传动与同步带传动的复合运动,形成螺旋线捆绑轨迹以精准控角,集成张力控制机构稳定布条张力、减少误差.在 EDEM中建立根土复合体离散元模型,经剪切试验和坚实度试验验证,相对误差小于5%,以土壤留存率和布条留存率为评价指标,开展捆绑起吊装箱仿真的三因素二次回归正交试验.[结果]正交试验得到斜捆 18.5圈、捆绑角度 47°、捆绑张力 20 N的优化参数,该参数下土壤留存率 85.10%、布条留存率 26.66%,经实际起吊装箱试验验证,与仿真结果最大相对误差均小于6%,参数可靠.设计泡沫土球试验台开展台架试验,确定圆周步进电机 76.5 r·min-1、上下步进电机 45 r·min-1 的最优转速组合,其张力波动率≤6%,整机捆绑时间≤210 s.[结论]采用该转速组合对 0.9~1.5 m直径大树土球进行林间试验,与手工捆绑相比,整体捆绑效率最大提升39.69%,土壤留存率最大提升8.41%.装置整机质量10.75 kg,单人可完成安装、捆绑与拆卸,大幅降低劳动强度.起吊装箱时土壤少量掉落、根系无损伤,验证了装置实用性,为大树移植机械化提供可靠方案.
[Objective]Current manual binding soil balls of large tree roots is labour-intensive,requiring three-person coordination.To address the issues of manual reliance,low efficiency,and lack of available machinery in binding soil balls of large tree roots during transplantation,this paper designs an in-situ binding apparatus for large tree root soil balls along with its binding strategy.[Method]By analysing manual binding trajectories,a modular positioning clamping mechanism was designed.This mechanism was adjusted radially with ten fastening bolts to accommodate large trees with trunk diameters ranging from 150 to 220 mm,ensuring coaxial alignment with the trunk.A composite motion combining gear-ring meshing transmission and synchronous belt drive were used to form a helical binding trajectory for precise angular control.An integrated tension control mechanism was used to stabilize strap tension and reduce errors.A discrete element model of the root-soil composite was established in EDEM.Shear and firmness tests validated a relative error below 5%.A three-factor quadratic orthogonal test was conducted for bundling and lifting container simulations,using soil retention rate and strap retention rate as evaluation metrics.[Result]Orthogonal tests yielded optimised parameters:18.5 diagonal wraps,47° binding angle,and binding tension of 20 N.Under these conditions,soil retention rate reached 85.10%and fabric retention rate was 26.66%.The actual container lifting experiments verified that the maximum relative error was below 6%compared to simulation results,indicating the parameter reliability.A foam root ball test rig was designed for bench testing,determining the optimal speed combination with the circumferential stepper motor of 76.5 r·min-1 and the vertical stepper motors of 45 r·min-1.This configuration achieved a tension fluctuation rate≤6%and a total binding time≤210 s.[Conclusion]Field trials were conducted on tree root balls with diameters ranging from 0.9 to 1.5 m using this speed combination.The overall bundling efficiency increases by a maximum of 39.69%and the soil retention rate increases a maximum of 8.41%compared to manual bundling.The device weighs 10.75 kg,and can be installed,wrapped,and disassembled by a single operator,significantly reducing labour intensity.When lifting and packing,a small amount of soil falls off and the root system is not damaged,validating the device's practicality,and providing a reliable solution for mechanizing large tree transplantation.
喻陈楠;王升帅;顾星辰;姚坤;伍永红;陈建能
浙江理工大学机械工程学院 杭州 310018||浙江省农业智能感知与机器人重点实验室 杭州 310018浙江理工大学机械工程学院 杭州 310018浙江理工大学机械工程学院 杭州 310018浙江理工大学机械工程学院 杭州 310018浙江理工大学机械工程学院 杭州 310018浙江理工大学机械工程学院 杭州 310018||浙江省农业智能感知与机器人重点实验室 杭州 310018
农业科技
大树土球原位捆绑模块化设计离散元响应面分析控制策略
big tree soil ballsin-situ bundlingmodular designdiscrete elementresponse surface analysiscontrol strategy
《林业科学》 2026 (5)
107-119,13
浙江省教育厅科研项目(Y202456649)浙江省自然科学基金项目(LQN26E050030).
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