Characteristic Evaluation of a Shrouded Propeller Mechanism for a Magnetic Actuated Microrobot

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Given that the current microrobot cannot achieve fixed-point and quantitative drug application in the gastrointestinal (GI) tract, a targeted drug delivery microrobot is proposed, and its principle and characteristics are studied. Through the control of an external magnetic field, it can actively move to the affected area to realize the targeted drug delivery function. The microrobot has a cam structure connected with a radially magnetized permanent magnet, which can realize two movement modes: movement and targeted drug delivery. Firstly, the magnetic actuated capsule microrobotic system (MACMS) is analyzed. Secondly, the dynamic model and quantitative drug delivery model of the targeted drug delivery microrobot driven by the spiral jet structure are established, and the motion characteristics of the targeted drug delivery microrobot are simulated and analyzed by the method of Computational Fluid Dynamics (CFD). Finally, the whole process of the targeted drug delivery task of the microrobot is simulated. The results show that the targeted drug delivery microrobot can realize basic movements such as forward, backward, fixed-point parking and drug delivery through external magnetic field control, which lays the foundation for gastrointestinal diagnosis and treatment.

Section: Motion Characteristics Of Microrobotmentioning

confidence: 99%

Performance Evaluation of a Magnetically Driven Microrobot for Targeted Drug Delivery

Cai

Zhang

et al. 2021

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“…In contrast, relatively large areas of the spherical surface were enveloped by the tool trace of eccentric V-groove finish (Figure 8b). This is because the eccentricity of the two abrasive plates increased the range of the rotating angels θ and ϕ, which subsequently increased the area of envelopment by the tool trace [29,30]. As for CMRF method, the range of the rotating angel is larger than that of eccentric V-groove finish due to the combination of the plates eccentricity and the flexible of the contact between the ball surface and magnetorheological pads, which is in turn readily to form a fully-enveloped tool trace on the spherical surface [31].…”

Section: Formation Of the Trace And Distribution Of The Contact Pointsmentioning

confidence: 99%

Polishing of Silicon Nitride Ceramic Balls by Clustered Magnetorheological Finish

Xiao

Mei

et al. 2020

In this study, a novel finishing method, entitled clustered magnetorheological finish (CMRF), was proposed to improve surface finish of the silicon nitride ( Si 3 N 4 ) balls with ultra fine precision. The effects of different polishing parameters including rotation speeds, eccentricities and the machining gaps on surface finish of Si 3 N 4 balls were investigated by analyzing the roughness, sphericity and the micro morphology of the machined surface. The experimental results showed that the polishing parameters significantly influenced the surface finish. The best surface finish was obtained by using the polishing parameters: the machining gap of 0.8 mm, the eccentricity of 10 mm and the rotation ratio of 3/4. To further investigate the influence of the polishing parameters on the surface finish, an analytical model was also developed to analyze the kinematics of the ceramic ball during CMRF process. The resulting surface finish, as a function of different polishing parameters employed, was evaluated by analyzing the visualized finishing trace and the distribution of the contact points. The simulative results showed that the distribution and trace of the contact points changed with different polishing parameters, which was in accordance with the results of experiments.

“…We measured the magnetic field in the region of interest of the Helmholtz coils using our proposed measurement system [32]. The Gauss meter (TM701, KANETEC, Nagano, Japan) was used to measure the magnetic field between each Helmholtz coil, as shown in Figure 7a.…”

Section: Conceptual Design Of Magnetic Actuated Capsule Microrobotmentioning

confidence: 99%

“…Meanwhile, the microrobot rotates synchronously with the changing frequency of rotational magnetic field, due to a pure magnetic moment is generated as a dipole of magnet attempts to align with the local magnetic field. The magnetic force and magnetic torque is defined by Equations (12) and (13) [32]. T=VM×B F=Vfalse(M⋅∇false)B where, V and M represent the volume and average magnetization of the magnetically microrobot, respectively.…”

Section: Screw Jet Motion Mechanismmentioning

confidence: 99%

Performance Evaluation of a Magnetically Actuated Capsule Microrobotic System for Medical Applications

Zhang

Guo

et al. 2018

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The paper aims to propose a magnetic actuated capsule microrobotic system, which is composed of a magnetically actuated microrobot with a screw jet mechanism, a driving system, and a positioning system. The magnetically actuated microrobot embedded an O-ring magnet as an actuator has potential for achieving a particular task, such as medical diagnose or drug delivery. The driving system composes of a three axes Helmholtz coils to generate a rotational magnetic field for controlling the magnetically actuated microrobot to realize the basic motion in pipe, e.g., forward/backward motion and upward/downward motion. The positioning system is used to detect the pose of the magnetically actuated microrobot in pipe. We will discuss the shape of the Helmholtz coils and the magnetic field around the O-ring magnet to obtain an optimal performance of the magnetically actuated microrobot. The experimental result indicated that the microrobot with screw jet motion has a flexible movement in pipe by adjusting the rotational magnetic field plane and the magnetic field changing frequency.