Analysis of the constraint relation between ground and self-adaptive mobile mechanism of a transformable wheel-track robot

Li, ZhiQing; Ma, Shugen; Li, Bin; Wang, Minghui; Wang, Yuechao

doi:10.1007/s11431-010-4228-5

Cited by 21 publications

(5 citation statements)

References 10 publications

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“…4(a). The supporting leg could be simplified to the two-force bar [12][13][14]. The force on the pin A that is contacted with the pipe wall is analyzed in Fig.…”

Section: A Mathematical Modelingmentioning

confidence: 99%

Finite Element Analysis Based Design of Mobile Robot for Removing Plug Oil Well

Tian¹,

Liu

Lin³

et al. 2013

JCP

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In order to develop the mobile robot for removing the plug oil well, the robot was designed based on the wheeltype and leg-type robot mechanism. A well functioning prototype has been manufactured. To demonstrate the validity and the benefit of the mobile robot, supporting mechanism and guiding rod were chosen to design based on the FEM. The mathematical model of the supporting mechanism is established and the mechanical property is analyzed using the FEM. The deformation and stress of some components of the supporting mechanism and the guiding rod is investigated. The results show that the supporting mechanism and the guiding rod have excellent performance with little displacement and small stress under working condition. The strength and rigidity of supporting mechanism and the guiding rod are good enough to ensure the reliability of the whole robot mechanism.

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“…4(a). The supporting leg could be simplified to the two-force bar [12][13][14]. The force on the pin A that is contacted with the pipe wall is analyzed in Fig.…”

Section: A Mathematical Modelingmentioning

confidence: 99%

Finite Element Analysis Based Design of Mobile Robot for Removing Plug Oil Well

Tian¹,

Liu

Lin³

et al. 2013

JCP

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“…Some common technologies and expertise technologies of unmanned autonomous systems have attracted researchers' wide attention, such as sensing technology [54,56], human-robot interaction technology [45], information communication technology [20], path planning technology [32,57,58], multi-platform collaboration technology [15,35,36,50,59,60], movement and motion-control technology [17,61,62], autonomy energy technology [39], mission planning technology [13,16,63], and autonomous flight-control technology [31,34,64,65]. Ref.…”

Section: Key Technologies Of the Cobweb Evaluation Modelmentioning

confidence: 99%

Evaluation methods for the autonomy of unmanned systems

Wang

Liu

2012

Chin. Sci. Bull.

Self Cite

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Future military and civilian unmanned systems will be extensively used on land, under the sea, in air, and in space. Evaluation of their autonomy is critical to realize the autonomous operation ability of unmanned systems. This paper discussed the basic concepts of autonomy and the significance of autonomy evaluation, and then surveys and describes existing evaluating methods. Based on analyses of key technologies and these technologies' technical readiness levels, a cobweb evaluation model as a universal evaluation model has been used to evaluate unmanned systems. If the technology warps (aspects of autonomy) and wefts (levels of those aspects) of unmanned systems can be determined for the cobweb model, the model can handle the mutual coupling, high dimensions, and diversity of warp lines. This model potentially has wide application in evaluating various unmanned systems.

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“…Over the past few decades, extensive research has been conducted on mobile robots due to their ability to assist humans in performing hazardous tasks in complex and unpredictable environments, such as search and rescue operations, counterterrorism efforts, explosive removals, planetary exploration endeavors and so on. Based on their application scenarios and movement modes, mobile robots can be classified into wheeled robot (Chen et al , 2018; Zhang et al , 2020; Khan et al , 2021), tracked robot (Fiedeń and Bałchanowski, 2021; Cui et al , 2016; Li et al , 2011) and legged crawling robot (Xu and Ding, 2013; Su et al , 2020). These robots have shown broad applications in transportation (Fukui et al , 2020), life services (Mateo and Santivaez, 2021; Kamegawa et al , 2020) and other fields.…”

Section: Introductionmentioning

confidence: 99%

Gait and simulation analysis of quadruped crawling robot based on metamorphic structure

Pan,

Zhang,

Mei

et al. 2023

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Purpose This study aims to present a type of metamorphic mechanism-based quadruped crawling robot. The trunk design of the robot has a metamorphic mechanism, which endows it with excellent crawling capability and adaptability in challenging environments. Design/methodology/approach The robot consists of a metamorphic trunk and four series-connected three-joint legs. First, the walking and steering strategy is planned through the stability and mechanics analysis. Then, the walking and steering performance is examined using virtual prototype technology, as well as the efficacy of the walking and turning strategy. Findings The metamorphic quadruped crawling robot has wider application due to its variable trunk configuration and excellent leg motion space. The robot can move in two modes (constant trunk and trunk configuration transformation, respectively, while walking and rotating), which exhibits outstanding stability and adaptability in the examination and verification of prototypes. Originality/value The design can enhance the capacity of the quadruped crawling robot to move across a complex environment. The virtual prototype technology verifies that the proposed walking and steering strategy has good maneuverability and stability, which considerably expands the application opportunity in the fields of complicated scene identification and investigation.

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Analysis of the constraint relation between ground and self-adaptive mobile mechanism of a transformable wheel-track robot

Cited by 21 publications

References 10 publications

Finite Element Analysis Based Design of Mobile Robot for Removing Plug Oil Well

Finite Element Analysis Based Design of Mobile Robot for Removing Plug Oil Well

Evaluation methods for the autonomy of unmanned systems

Gait and simulation analysis of quadruped crawling robot based on metamorphic structure

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