TY - GEN

T1 - Design of a fully actuated electromagnetic bending actuator for endoscopic applications

AU - Wöhrmann, M.

AU - Dörbaum, M.

AU - Ponick, B.

AU - Mertens, A.

N1 - Funding Information: The authors thank the German Research Foundation (Deutsche Forschungsgemeinschaft) for supporting this research project.

PY - 2013

Y1 - 2013

N2 - This article presents a novel concept for a fully actuated electromagnetic bending actuator for endoscopic applications, resembling a snake in appearance and in flexibility. Flexib ility is reached by a clever arrangement of the individual a ctuator elements, each being tiltable by a defined angle. This tilting is realised by electromagnetism, and each element is able to take discrete angular positions. The different positions in workspace are reached by correspondingly controlling the individual elements within the actuator. In a first step, the operating principle and different types of actuators are described. Compared to rotary machines which can often be calculated by two-dimensional models, this actuator requires a three-dimensional calculation approach. The calculation can either be realised analytically, by a magnetic ne t-work or nu merically based on the Finite Element method. In this article, the numerical approach via the FEM software Maxwell is used. In doing so, different types of actuators are calculated and compared with each other. The calculated maps show a strong nonlinear dependence of the actuator torque on the angular pos ition as well as on the electrical e x-citation. In open state, the actuator torque is very small. When closed, it increases up to three powers of ten. On the one hand, the magnetic circu it and thus the actuator design must be optimised with respect to higher actuator torques when open. On the other hand, high electrical excitation is required to rotate the actuator, whereas maintaining the actuator in its closed state just requires a small electrical excitation.

AB - This article presents a novel concept for a fully actuated electromagnetic bending actuator for endoscopic applications, resembling a snake in appearance and in flexibility. Flexib ility is reached by a clever arrangement of the individual a ctuator elements, each being tiltable by a defined angle. This tilting is realised by electromagnetism, and each element is able to take discrete angular positions. The different positions in workspace are reached by correspondingly controlling the individual elements within the actuator. In a first step, the operating principle and different types of actuators are described. Compared to rotary machines which can often be calculated by two-dimensional models, this actuator requires a three-dimensional calculation approach. The calculation can either be realised analytically, by a magnetic ne t-work or nu merically based on the Finite Element method. In this article, the numerical approach via the FEM software Maxwell is used. In doing so, different types of actuators are calculated and compared with each other. The calculated maps show a strong nonlinear dependence of the actuator torque on the angular pos ition as well as on the electrical e x-citation. In open state, the actuator torque is very small. When closed, it increases up to three powers of ten. On the one hand, the magnetic circu it and thus the actuator design must be optimised with respect to higher actuator torques when open. On the other hand, high electrical excitation is required to rotate the actuator, whereas maintaining the actuator in its closed state just requires a small electrical excitation.

UR - http://www.scopus.com/inward/record.url?scp=84992420113&partnerID=8YFLogxK

M3 - Conference contribution

AN - SCOPUS:84992420113

T3 - GMM-Fachberichte

SP - 152

EP - 157

BT - Innovative Klein- und Mikroantriebstechnik

PB - VDE Verlag GmbH

T2 - 9. GMM/ETG Fachtagung Innovative Klein- und Mikroantriebstechnik - 9th GMM/ETG Symposium on Innovative Small Drives and Micro-Motor Systems

Y2 - 19 September 2013 through 20 September 2013

ER -