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工程设计学报
工程设计学报  2025, Vol. 32 Issue (6): 845-855    DOI: 10.3785/j.issn.1006-754X.2025.05.148
机械零部件与装备设计     
矿用锚网绑扎装置手持执行器传动系统的设计与应用
田立勇1(),刘毅1,于宁1,杨秀宇1,2,包佳豪1,张海建1
1.辽宁工程技术大学 机械工程学院,辽宁 阜新 123000
2.中煤天津设计工程有限责任公司,天津 300120
Design and application of handheld actuator transmission system for mine anchor net binding device
Liyong TIAN1(),Yi LIU1,Ning YU1,Xiuyu YANG1,2,Jiahao BAO1,Haijian ZHANG1
1.School of Mechanical Engineering, Liaoning Technical University, Fuxin 123000, China
2.China Coal Tianjin Design Engineering Company, Tianjin 300120, China
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摘要:

针对煤矿掘进工作面人工绑扎锚网效率低的问题,提出了一种矿用锚网绑扎装置。手持执行器是矿用锚网绑扎装置的终端执行器,为深入理解其工作机理并验证其设计可靠性,利用SolidWorks软件和ANSYS软件分别对绑扎机构的送丝、切丝与拧丝过程进行了仿真分析,得出工作过程中送丝齿轮的峰值转矩为0.19 N·m,切丝片的峰值转矩为0.54 N·m,拧丝轴的峰值转矩为0.40 N·m。运用ADAMS软件对绑扎机构的传动系统进行了多体动力学仿真,得到了传动部件运行的速度特性曲线以及齿轮啮合传递的负载特性曲线。基于ANSYS软件对绑扎机构的齿轮啮合运动进行了有限元仿真分析,得出了啮合过程中齿轮结合面的应力分布云图,并根据计算的许用应力对齿轮的接触疲劳强度和弯曲疲劳强度进行了校核与验证。最后,搭建了锚网绑扎装置样机与手持执行器输入测试平台,并开展了绑扎性能验证实验。实验结果表明:手持执行器的性能与仿真分析结果基本吻合,绑扎动作连贯高效,单个绑扎操作循环用时1.8 s,绑扎效果符合设计要求且满足实际使用需求。研究结果为矿用锚网绑扎装置的优化设计与工程应用提供了理论依据。
关键词: 锚网绑扎手持执行器绑扎机构传动系统仿真分析    
Abstract:

Aiming at the problem of low efficiency of manual binding of anchor nets in coal mine tunneling faces, a mine anchor net binding device is proposed. The handheld actuator is the terminal actuator of the mine anchor net binding device. In order to deeply understand its working mechanism and verify the design reliability, the wire feeding, wire cutting and wire twisting processes of the binding mechanism were simulated and analyzed by using SolidWorks software and ANSYS software, respectively. It was concluded that the peak torque of the wire feeding gear during operation was 0.19 N·m, the peak torque of the slicing sheet was 0.54 N·m, and the peak torque of the wire twisting shaft was 0.40 N·m. The multi-body dynamics simulation for the transmission system of the binding mechanism was carried out by using ADAMS software, and the speed characteristic curve of the transmission components during operation and the load characteristic curve of gear meshing transmission were obtained. Based on the ANSYS software, the finite element simulation analysis for the gear meshing motion of the binding mechanism was carried out, and the stress distribution cloud maps of the gear mating surface during the meshing process were obtained. The contact fatigue strength and bending fatigue strength of the gears were checked and verified according to the calculated allowable stress. Finally, an anchor net binding device prototype and a handheld actuator input test platform were built, and the binding performance verification experiments were carried out. The experimental results showed that the performance of the handheld actuator was basically consistent with the simulation analysis results. The binding action was continuous and efficient, and the time for a single binding operation cycle was 1.8 s. The binding effect met the design requirements and actual application needs. The research results provide a theoretical basis for the optimal design and engineering application of the mine anchor net binding device.
Key words: anchor net binding    handheld actuator    binding mechanism    transmission system    simulation analysis
收稿日期: 2025-07-07 出版日期: 2025-12-30
CLC:  TD 353  
基金资助: 国家自然科学基金面上项目(52174143)
作者简介: 田立勇(1979—),男,教授,博士,从事机电一体化研究,E-mail: tianliyong@lntu.edu.cn,https://orcid.org/0000-0002-8690-5550
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引用本文:

田立勇,刘毅,于宁,杨秀宇,包佳豪,张海建. 矿用锚网绑扎装置手持执行器传动系统的设计与应用[J]. 工程设计学报, 2025, 32(6): 845-855.

Liyong TIAN,Yi LIU,Ning YU,Xiuyu YANG,Jiahao BAO,Haijian ZHANG. Design and application of handheld actuator transmission system for mine anchor net binding device[J]. Chinese Journal of Engineering Design, 2025, 32(6): 845-855.

链接本文:

https://www.zjujournals.com/gcsjxb/CN/10.3785/j.issn.1006-754X.2025.05.148        https://www.zjujournals.com/gcsjxb/CN/Y2025/V32/I6/845

图1  矿用锚网绑扎装置结构组成
图2  手持执行器的传动部件
图3  矿用锚网绑扎装置的动力传递框图
图4  绑扎机构传动结构简图
图5  送丝机构仿真模型
图6  送丝转矩仿真曲线
图7  切丝机构仿真模型
图8  切丝转矩仿真曲线
图9  拧丝机构仿真模型
图10  拧丝转矩仿真曲线
图11  绑扎机构的输入转速曲线
图12  绑扎机构的输出转矩曲线
图13  绑扎机构传动部件的转速曲线
图14  绑扎机构齿轮的啮合转矩曲线
应力小圆柱齿轮大圆柱齿轮小圆锥齿轮大圆锥齿轮小送丝齿轮大送丝齿轮
许用齿面接触应力719688719688719688
许用齿根弯曲应力414343414343414343
齿面接触应力449309643455125114
齿根弯曲应力31.028.970.076.417.216.7
表1  绑扎机构齿轮的啮合应力计算结果 (MPa)
图15  绑扎机构齿轮的啮合应力云图
应力小圆柱齿轮大圆柱齿轮小圆锥齿轮大圆锥齿轮小送丝齿轮大送丝齿轮
齿面接触应力57855564857711983.4
齿根弯曲应力33527721610338.127.6
表2  绑扎机构齿轮的啮合应力仿真结果 (MPa)
图16  绑扎效果测试
组数12345
绑扎时间/s1.821.731.781.881.81
组数678910
绑扎时间/s1.791.841.851.711.74
表3  单次绑扎操作的时间
图17  手持执行器输入测试平台
图18  手持执行器的输入转矩与输入转速曲线
  
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