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Li Cheng. Motion Simulation of Reverse Reconstructed D-bale knotter and Bill Hook Mechanical Analysis during Straw Baling. Beingjing: China Agricultural University, 2015.ChengLiBeingjingChina Agricultural University2015Search in Google Scholar
Zhang Anqi, Chen Longjian, Dong Hao, etc. Spatial Structure Parameter Analysis of Rope Cutting and Releasing Mechanism of D-knotter. Transactions of the Chinese Society for Agricultural Machinery, 2017, 48(01), pp. 73–80.AnqiZhangLongjianChenHaoDongetc.Spatial Structure Parameter Analysis of Rope Cutting and Releasing Mechanism of D-knotter201748017380Search in Google Scholar
Wei Ruitao. Research on The Precision Design of the Knotter of Square Baler. Inner Mongolia: Inner Mongolia University of Technology, 2018.RuitaoWeiInner MongoliaInner Mongolia University of Technology2018Search in Google Scholar
Yin Jianjun, Li Shuang, Li Yaoming. Kinematic Simulation and Time Series Analysis of D-knotter and Its Ancillary Mechanisms. Transactions of The Chinese Society of Agricultural Machinery | T Chin Soc Agric Mach, 2011, 42(06), pp. 103–107.JianjunYinShuangLiYaomingLiKinematic Simulation and Time Series Analysis of D-knotter and Its Ancillary Mechanisms20114206103107Search in Google Scholar
Li Shuang, Yin Jianjun, Li Yaoming. Kinematic Characteristic Analysis of D-knotter and Its Ancillary Mechanisms. Machine Design and Research, 2011, 27(01), pp. 18–21.ShuangLiJianjunYinYaomingLiKinematic Characteristic Analysis of D-knotter and Its Ancillary Mechanisms201127011821Search in Google Scholar
Zhang Shaoying, Li Haitao, Cao Qinghe, etc. Design of Key Transmission Mechanism of Double-α-knot Knotter. Transactions of the Chinese Society for Agricultural Machinery, 2013, 44(12), pp. 74–79.ShaoyingZhangHaitaoLiQingheCaoetc.Design of Key Transmission Mechanism of Double-α-knot Knotter201344127479Search in Google Scholar
Li Hui, He Jin, Li Hongwen, etc. Spatial Parameters of Knotters of Square Balers. Transactions of the Chinese Society for Agricultural Machinery, 2013, 44(08), pp. 99–105.HuiLiJinHeHongwenLietc.Spatial Parameters of Knotters of Square Balers2013440899105Search in Google Scholar
Kang H, Wen J T. EndoBot: a robotic assistant in minimally invasive surgeries. IEEE International Conference on Robotics and Automation. 2001, pp. 2031–2036.KangHWenJ TEndoBot: a robotic assistant in minimally invasive surgeries200120312036Search in Google Scholar
Wang Huijuan. The Behaviors of Suturing and Knot-tying in the Robot-assisted Minimally Invasive Surgery. Tianjin: Tianjin University, 2010.HuijuanWangTianjinTianjin University2010Search in Google Scholar
Chen Tianchi. Study on Mechanical Properties of Kelp and Design of Mechanisms for knotting Kelp. Jiangsu: Southeast University, 2018.TianchiChenJiangsuSoutheast University2018Search in Google Scholar
Wang Xiaoqiang. RESEARCH ON KEY TECHNOLOGIES OF KELP-KNOTTED MACHINE BASED ON SPIRAL CLAMPING CLAWS. Harbin: Harbin Institute of Technology, 2012.XiaoqiangWangHarbinHarbin Institute of Technology2012Search in Google Scholar
Chen Junrong. RESEARCH ON THE FORMATION PRINCIPLE OF ROPE KNOTS AND NEW KNOTTING DEVICE. Shanghai: Shanghai University of Engineering Science, 2020.JunrongChenShanghaiShanghai University of Engineering Science2020Search in Google Scholar
Yue L, Cao Y, Wang S, et al. Twisting Knot Tying Method of Suture ---A Novel Method for Robotic Knot Tying. IEEE/ICME International Conference on Complex Medical Engineering. 2007, pp. 87–91.YueLCaoYWangSTwisting Knot Tying Method of Suture ---A Novel Method for Robotic Knot Tying2007879110.1109/ICCME.2007.4381698Search in Google Scholar
Lu B, Chu H K, Cheng L. Dynamic trajectory planning for robotic knot tying. IEEE International Conference on Real-time Computing and Robotics (RCAR). 2016, pp. 180–185.LuBChuH KChengLDynamic trajectory planning for robotic knot tying201618018510.1109/RCAR.2016.7784022Search in Google Scholar
H. Kang, J.T. Wen, et al. Robotic knot tying in minimally invasive surgeries. IEEE/RSJ International Conference on Intelligent Robots and Systems. 2002, pp. 1421–1426.KangH.WenJ.T.Robotic knot tying in minimally invasive surgeries200214211426Search in Google Scholar
Ramli M S B, Azlan N Z. Design and development of an anthropomorphic shoe-tying robot. Mecatronics. 2015, pp. 377–382.RamliM S BAzlanN ZDesign and development of an anthropomorphic shoe-tying robot2015377382Search in Google Scholar
Lu B, Chu H K, Cheng L. Dynamic trajectory planning for robotic knot tying. IEEE International Conference on Real-time Computing and Robotics. 2016, pp. 180–185.LuBChuH KChengLDynamic trajectory planning for robotic knot tying201618018510.1109/RCAR.2016.7784022Search in Google Scholar
He L, Zhang Q, Charvet H J, et al. A Robotic Knot-Tying Platform for High-Trellis Hop Twining. IFAC Papers On Line, 2013, 46(4), pp. 89–94.HeLZhangQCharvetH JA Robotic Knot-Tying Platform for High-Trellis Hop Twining2013464899410.3182/20130327-3-JP-3017.00023Search in Google Scholar
Yamakawa Y, Namiki A, Ishikawa M, et al. One-handed knotting of a flexible rope with a high-speed multi-fingered hand having tactile sensors. IEEE/RSJ International Conference on Intelligent Robots and Systems. 2007, pp. 703–708.YamakawaYNamikiAIshikawaMOne-handed knotting of a flexible rope with a high-speed multi-fingered hand having tactile sensors200770370810.1109/IROS.2007.4399379Search in Google Scholar
Luo Dongsheng. RESEARCH ON AUTOMATIC KNOTTING DEVICE FOR ROBING[D]. Shanghai: Donghua University, 2014.DongshengLuoShanghaiDonghua University2014Search in Google Scholar
Bai Maodong, Yang Jixin, Wang Xuejun, etc. A new method of double flat kelp knotting. Journal of Dalian Polytechnic University, 2017, 36(04), pp. 300–303.MaodongBaiJixinYangXuejunWangetc.A new method of double flat kelp knotting20173604300303Search in Google Scholar
Li Zhe, Wang Yurui, Tang Jian, etc. Research of kelp-knot principle based on catenary theory. Chinese Journal of Engineering Design, 2011, 18(04), pp. 260–264.ZheLiYuruiWangJianTangetc.Research of kelp-knot principle based on catenary theory20111804260264Search in Google Scholar