Kinematics of Spherical Robots Rolling over 3D Terrains

Moazami, Saeed; Zargarzadeh, Hassan; Паланки, Сринивас

doi:10.1155/2019/7543969

Cited by 12 publications

(9 citation statements)

References 43 publications

(52 reference statements)

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“…Since each of DC motors has a unique mechanical specification (i.e., torque constant and nominal current), the corresponding load torque at each measured current value is calculated by using Eq. (11), taken from the Maxon Motor datasheet, to verify that both motors operate within the suggested continuous range by the manufacturer company. The torque constant K m is 38.5 mNm/A and 30.2 mNm/A, and the nominal current I 0 is 236 mA and 137 mA for the 200 W and 150 W DC motors, respectively.…”

Section: Locomotion Mechanism Experimental Resultsmentioning

confidence: 99%

“…However, there are several possibilities: the slippage between tracks and the floor; uneven wear on tracks; and possible shocks during the transition between surfaces. Although some of the measurements pass the 10.8 A (405 mNm) maximum continuous current (torque) of the 200 W motor, the overall performance (11) does not exceed the continuous operation range, so the robot can smoothly operate in various conditions. This can be seen clearly from the 8 A difference between the measured current on a flat surface and an inclined one.…”

Section: Locomotion Mechanism Experimental Resultsmentioning

confidence: 99%

“…However, the mobile platforms introduced in [7] and [8] can also be known as two early experimental efforts in design and implementation of mobile robot platforms which were potentially suited for USAR, though the authors did not explicitly mention their USAR applications. Later on, rescue robotics started getting more attentions gradually among the mobile robotics research community [9], which led to developing rescue robots with a variety of locomotion mechanisms such as spherical [10,11], legged [12], wheeled [13], and tracked [14] locomotion.…”

Section: Introductionmentioning

confidence: 99%

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Design and implementation of a maxi-sized mobile robot (Karo) for rescue missions

et al. 2021

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Rescue robots are expected to carry out reconnaissance and dexterity operations in unknown environments comprising unstructured obstacles. Although a wide variety of designs and implementations have been presented within the field of rescue robotics, embedding all mobility, dexterity, and reconnaissance capabilities in a single robot remains a challenging problem. This paper explains the design and implementation of Karo, a mobile robot that exhibits a high degree of mobility at the side of maintaining required dexterity and exploration capabilities for urban search and rescue (USAR) missions. We first elicit the system requirements of a standard rescue robot from the frameworks of Rescue Robot League (RRL) of RoboCup and then, propose the conceptual design of Karo by drafting a locomotion and manipulation system. Considering that, this work presents comprehensive design processes along with detail mechanical design of the robot’s platform and its 7-DOF manipulator. Further, we present the design and implementation of the command and control system by discussing the robot’s power system, sensors, and hardware systems. In conjunction with this, we elucidate the way that Karo’s software system and human–robot interface are implemented and employed. Furthermore, we undertake extensive evaluations of Karo’s field performance to investigate whether the principal objective of this work has been satisfied. We demonstrate that Karo has effectively accomplished assigned standardized rescue operations by evaluating all aspects of its capabilities in both RRL’s test suites and training suites of a fire department. Finally, the comprehensiveness of Karo’s capabilities has been verified by drawing quantitative comparisons between Karo’s performance and other leading robots participating in RRL.

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Section: Locomotion Mechanism Experimental Resultsmentioning

confidence: 99%

Section: Locomotion Mechanism Experimental Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Design and implementation of a maxi-sized mobile robot (Karo) for rescue missions

et al. 2021

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“…We have described the mechanical design of the intermeshed rotary thrusters, the outer gridshell and the full robot assembly in detail. Also, as per the proposed classification and the constraints of SRs in [25], the dynamics equations for SRs rolling over 3D terrains are derived. A modified pure pursuit method [26] is utilized for the path tracking control problem of derived models.…”

Section: Et Al Used Fixed Radiallymentioning

confidence: 99%

“…4) The moments generated and the frictional force are always enough to provide the required driving force to the robot. Regarding to the kinematics equations derived by Moazami et al [25] based on the different categories of the SRs rolling over the 3D terrains, the transformation between the world frame W co-ordinates and the tangent plane frame T coordinates is given by:…”

Section: E Overall Mechanical Assemblymentioning

confidence: 99%

Design, Modelling and Control of SPIROS: The Six Propellers and Intermeshing Rotors Based Omnidirectional Spherical Robot

Phalak

2021

Preprint

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Since the past few decades, several designs and control methods have been developed for the Spherical Robots (SRs) with thoroughly analyzed mechanics on generalized 3D terrains. But the vertical motion and the steep inclination maneuver has been an unsolved problem with the existing SR's driving mechanisms. Also, the possibilities of wind-powered or air-propelled SRs have not been fully explored. This paper introduces the new Omnidirectional Spherical Robot mechanism named SPIROS: The Six Propeller and Intermeshed Rotor based Omnidirectional Spherical Robot. The SPIROS is driven by a novel octahedral arrangement of six intermeshed rotary air thrusters placed in the Goldberg Polyhedral shaped spherical gridshell. The advantage of the proposed design lies in its airpowered propulsion, which improves on the obstacle avoidance and the slope climbing abilities. The robot's dynamic models are derived using the existing kinematical models of the Continuous Rolling Spherical Robots (CR-SR), with subcategories, triple axes rolling (3R-SR), dual axes rolling (2R-SR) and rolling and turning (RT-SR) spherical robots. The path tracking control scheme based on the pure pursuit algorithm is presented. Simulations are carried out in MATLAB and Simulink to validate the developed models and the effectiveness of the proposed control schemes.

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Mechanical design and energy absorption analysis of spherical honeycomb core for soft-landing device buffer shell

2020

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Kinematics of Spherical Robots Rolling over 3D Terrains

Cited by 12 publications

References 43 publications

Design and implementation of a maxi-sized mobile robot (Karo) for rescue missions

Design and implementation of a maxi-sized mobile robot (Karo) for rescue missions

Design, Modelling and Control of SPIROS: The Six Propellers and Intermeshing Rotors Based Omnidirectional Spherical Robot

Mechanical design and energy absorption analysis of spherical honeycomb core for soft-landing device buffer shell

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