Modeling and analysis of electric field and electrostatic adhesion force generated by interdigital electrodes for wall climbing robots

A model is presented for the analysis of the electric field and electrostatic adhesion force produced by interdigital electrodes. Assuming that the potential varies linearly with distance in inter-electrode gaps, the potential distribution on the electrode plane is obtained by taking the first-order Taylor series approximation. The expressions of electric field components are then derived by solving the Laplace equation for the electrical potential in each subregion. The electrostatic adhesion force is calculated using the Maxwell stress tensor formulation. The dynamic properties of the electric field and electrostatic adhesion force are assessed by evaluating the transient response of the field and force under a step in applied voltages. To verify the model developed, an experimental study is carried out in conjunction with the theoretical analysis to evaluate the adhesion performance of an electrode panel on a glass pane. A double tracked wall climbing robot is designed and tested on various wall surfaces. The limit of the approximation method of the inter-electrode potential is discussed. It is found that vacuum suction force is involved in the adhesion. The influence of this vacuum suction force on electrostatic adhesion is also discussed. The results of this work would provide support for theoretical guidelines and system optimization for the electrostatic adhesion technology applied to wall climbing robots.

[1]  Zhengwen Zhang Modeling and analysis of electrostatic force for robot handling of fabric materials , 1999 .

[2]  H. Morgan,et al.  The dielectrophoretic and travelling wave forces generated by interdigitated electrode arrays: analytical solution using Fourier series , 2001 .

[3]  Roy Kornbluh,et al.  Electroadhesive robots—wall climbing robots enabled by a novel, robust, and electrically controllable adhesion technology , 2008, 2008 IEEE International Conference on Robotics and Automation.

[4]  D. Marcuse Electrostatic field of coplanar lines computed with the point matching method , 1989 .

[5]  Peter R. C. Gascoyne,et al.  A theoretical method of electrical field analysis for dielectrophoretic electrode arrays using Green's theorem , 1996 .

[6]  Ronald Pethig,et al.  Selective dielectrophoretic confinement of bioparticles in potential energy wells , 1993 .

[7]  Shao Ju Woo,et al.  Electric field and force modeling for electrostatic levitation of lossy dielectric plates , 2010 .

[8]  G. Fuhr,et al.  Three-dimensional electric field traps for manipulation of cells--calculation and experimental verification. , 1993, Biochimica et biophysica acta.

[9]  Hywel Morgan,et al.  Numerical solution of the dielectrophoretic and travelling wave forces for interdigitated electrode arrays using the finite element method , 2002 .

[10]  Hermann A. Haus,et al.  Electromagnetic Fields And Energy , 1989 .

[11]  K. Yatsuzuka,et al.  Fundamental characteristics of electrostatic wafer chuck with insulating sealant , 1998, Conference Record of 1998 IEEE Industry Applications Conference. Thirty-Third IAS Annual Meeting (Cat. No.98CH36242).

[12]  A. Yamamoto,et al.  Wall Climbing Mechanisms Using Electrostatic Attraction Generated by Flexible Electrodes , 2007, 2007 International Symposium on Micro-NanoMechatronics and Human Science.