Walking model and planning algorithm of the over-obstacle pipe climbing robot

[1] Fukui T, Fujisawa H, Otaka K, Fukuoka Y (2019) Autonomous gait transition and galloping over unperceived obstacles of a quadruped robot with CPG modulated by vestibular feedback. Robotics and Autonomous Systems 111:1–19. FukuiT FujisawaH OtakaK FukuokaY 2019 Autonomous gait transition and galloping over unperceived obstacles of a quadruped robot with CPG modulated by vestibular feedback Robotics and Autonomous Systems 111 1 19 10.1016/j.robot.2018.10.002 Search in Google Scholar

[2] Hak L, Hettinga FJ, Duffy KR, Jackson J, Sandercock GRH (2019) The concept of margins of stability can be used to better understand a change in obstacle crossing strategy with an increase in age. Journal of biomechanics 84:147–152. HakL HettingaFJ DuffyKR JacksonJ SandercockGRH 2019 The concept of margins of stability can be used to better understand a change in obstacle crossing strategy with an increase in age Journal of biomechanics 84 147 152 10.1016/j.jbiomech.2018.12.03730642664 Search in Google Scholar

[3] Hong H, Kim D, Kim HS, Lee S, Kim J (2013) Contact angle estimation and composite locomotive strategy of a stair-climbing mobile platform. Robotics and Computer-Integrated Manufacturing 29/5:367–381. HongH KimD KimHS LeeS KimJ 2013 Contact angle estimation and composite locomotive strategy of a stair-climbing mobile platform Robotics and Computer-Integrated Manufacturing 29 5 367 381 10.1016/j.rcim.2013.03.001 Search in Google Scholar

[4] Huang HC, Li DH, Xue Z, Chen XL, Liu SY, Leng JX, Wei Y (2017) Design and performance analysis of a tracked wall-climbing robot for ship inspection in shipbuilding. Ocean Engineering 131:224–230. HuangHC LiDH XueZ ChenXL LiuSY LengJX WeiY 2017 Design and performance analysis of a tracked wall-climbing robot for ship inspection in shipbuilding Ocean Engineering 131 224 230 10.1016/j.oceaneng.2017.01.003 Search in Google Scholar

[5] Lee C, Chu B (2019) Three-Modular Obstacle-Climbing Robot for Cleaning Windows on Building Exterior Walls. International Journal of Precision Engineering and Manufacturing 20/8:1371–1380. LeeC ChuB 2019 Three-Modular Obstacle-Climbing Robot for Cleaning Windows on Building Exterior Walls International Journal of Precision Engineering and Manufacturing 20 8 1371 1380 10.1007/s12541-019-00138-5 Search in Google Scholar

[6] Liu YH, Seo TW (2018) AnyClimb-II: Dry-adhesive linkage-type climbing robot for uneven vertical surfaces. Mechanism and Machine Theory 124:197–210. LiuYH SeoTW 2018 AnyClimb-II: Dry-adhesive linkage-type climbing robot for uneven vertical surfaces Mechanism and Machine Theory 124 197 210 10.1016/j.mechmachtheory.2018.02.010 Search in Google Scholar

[7] Schmidt D, Berns K (2013) Climbing robots for maintenance and inspections of vertical structures–A survey of design aspects and technologies. Robotics and Autonomous Systems 61/12:1288–1305. SchmidtD BernsK 2013 Climbing robots for maintenance and inspections of vertical structures–A survey of design aspects and technologies Robotics and Autonomous Systems 61 12 1288 1305 10.1016/j.robot.2013.09.002 Search in Google Scholar

[8] Seo K, Cho S, Kim T, Kim HS, Kim J (2013) Design and stability analysis of a novel wall-climbing robotic platform (ROPE RIDE). Mechanism and Machine Theory 70:189–208. SeoK ChoS KimT KimHS KimJ 2013 Design and stability analysis of a novel wall-climbing robotic platform (ROPE RIDE) Mechanism and Machine Theory 70 189 208 10.1016/j.mechmachtheory.2013.07.012 Search in Google Scholar

[9] Kim D, Hong H, Kim HS, Kim J (2012) Optimal design and kinetic analysis of a stair-climbing mobile robot with rocker-bogie mechanism. Mechanism and Machine Theory 50:90–108. KimD HongH KimHS KimJ 2012 Optimal design and kinetic analysis of a stair-climbing mobile robot with rocker-bogie mechanism Mechanism and Machine Theory 50 90 108 10.1016/j.mechmachtheory.2011.11.013 Search in Google Scholar

[10] Li YW, Dai SM, Tian F, Zheng YW (2019) Stairs-climbing Capacity of a W-Shaped Track Robot. Transactions of FAMENA 43:13–24. LiYW DaiSM TianF ZhengYW 2019 Stairs-climbing Capacity of a W-Shaped Track Robot Transactions of FAMENA 43 13 24 10.21278/TOF.43Si102 Search in Google Scholar

[11] Morales R, Chocoteco J, Feliu V, Sira-Ramírez H (2013) Obstacle surpassing and posture control of a stair-climbing robotic mechanism. Control Engineering Practice 21/5:604–621. MoralesR ChocotecoJ FeliuV Sira-RamírezH 2013 Obstacle surpassing and posture control of a stair-climbing robotic mechanism Control Engineering Practice 21 5 604 621 10.1016/j.conengprac.2013.01.006 Search in Google Scholar

[12] Sorin MO, Nitulescu M (2012) Locomotion Over Common Types of Obstacles for a Legged Mobile Robot. Proceedings of the 14th IFAC Symposium on Information Control Problems in Manufacturing, Bucharest, Romania: 918–923. SorinMO NitulescuM 2012 Locomotion Over Common Types of Obstacles for a Legged Mobile Robot Proceedings of the 14th IFAC Symposium on Information Control Problems in Manufacturing Bucharest, Romania 918 923 Search in Google Scholar

[13] Yajima R, Nagatani K, Hirata Y (2019) Research on traversability of tracked vehicle on slope with unfixed obstacles: derivation of climbing-over, tipping-over, and sliding-down conditions. Advanced Robotics 33/20:1060–1071. YajimaR NagataniK HirataY 2019 Research on traversability of tracked vehicle on slope with unfixed obstacles: derivation of climbing-over, tipping-over, and sliding-down conditions Advanced Robotics 33 20 1060 1071 10.1080/01691864.2019.1668848 Search in Google Scholar

[14] Xu FY, Hu JL, Jiang GP (2015) The obstacle-negotiation capability of rod-climbing robots and the improved mechanism design. Journal of Mechanical Science and Technology 29/7:2975–2986. XuFY HuJL JiangGP 2015 The obstacle-negotiation capability of rod-climbing robots and the improved mechanism design Journal of Mechanical Science and Technology 29 7 2975 2986 10.1007/s12206-015-0628-6 Search in Google Scholar

[15] Du QL, Li Y, Liu SN (2019) Design of a micro pole-climbing robot. International Journal of Advanced Robotic Systems 16/3:1–11. DuQL LiY LiuSN 2019 Design of a micro pole-climbing robot International Journal of Advanced Robotic Systems 16 3 1 11 Search in Google Scholar

[16] Pfotzer L, Klemm S, Roennau A, Zöllner JM, Dillmann R (2017) Autonomous navigation for reconfigurable snakelike robots in challenging, unknown environments. Robotics and Autonomous Systems 89:123–135. PfotzerL KlemmS RoennauA ZöllnerJM DillmannR 2017 Autonomous navigation for reconfigurable snakelike robots in challenging, unknown environments Robotics and Autonomous Systems 89 123 135 10.1016/j.robot.2016.11.010 Search in Google Scholar

[17] Peidró A, Tavakoli M, Marín JM, Reinoso Ó (2019) Design of compact switchable magnetic grippers for the HyReCRo structure-climbing robot. Mechatronics 59:199–212. PeidróA TavakoliM MarínJM ReinosoÓ 2019 Design of compact switchable magnetic grippers for the HyReCRo structure-climbing robot Mechatronics 59 199 212 10.1016/j.mechatronics.2019.04.007 Search in Google Scholar

[18] Ma XL, Mao RQ (2018) Path planning for coal mine robot to avoid obstacle in gas distribution area. International Journal of Advanced Robotic Systems 15/1:1–6. MaXL MaoRQ 2018 Path planning for coal mine robot to avoid obstacle in gas distribution area International Journal of Advanced Robotic Systems 15 1 1 6 10.1177/1729881417751505 Search in Google Scholar

[19] Bykerk L, Quin P, Liu D (2019) A Method for Selecting the Next Best Angle-of-Approach for Touch-Based Identification of Beam Members in Truss Structures. IEEE sensors journal 19/10:3939–3949. BykerkL QuinP LiuD 2019 A Method for Selecting the Next Best Angle-of-Approach for Touch-Based Identification of Beam Members in Truss Structures IEEE sensors journal 19 10 3939 3949 10.1109/JSEN.2019.2896596 Search in Google Scholar

[20] Klein A, Haugland D (2019) Obstacle-aware optimization of offshore wind farm cable layouts. Annals of Operations Research 272:373–388. KleinA HauglandD 2019 Obstacle-aware optimization of offshore wind farm cable layouts Annals of Operations Research 272 373 388 10.1007/s10479-017-2581-5 Search in Google Scholar

[21] Liu DB, Li CY, Fan BH, Zhong PS (2018) Description method and statics analysis of optional location of robot particle on the inclined pipe. IPPTA: Quarterly Journal of Indian Pulp and Paper Technical Association 30/4:296–307. LiuDB LiCY FanBH ZhongPS 2018 Description method and statics analysis of optional location of robot particle on the inclined pipe IPPTA: Quarterly Journal of Indian Pulp and Paper Technical Association 30 4 296 307 Search in Google Scholar