Structural-Parametric Model of Electro Elastic Actuator for Nanotechnology and Biotechnology
Affiliation
Department of Intellectual Technical Systems, 124498, Moscow, Russia
Corresponding Author
Afonin SM, National Research University of Electronic Technology (MIET), Department of Intellectual Technical Systems, 124498, Moscow, Russia, E-mail: learner01@mail.ru
Citation
Afonin, S.M. Structural-Parametric Model of Electro Elastic Actuator for Nanotechnology and Biotechnology. (2018) J Pharm Pharmaceutics 5(1): 8-12.
Copy rights
© 2018 Afonin, S.M. This is an Open access article distributed under the terms of Creative Commons Attribution 4.0 International License.
Keywords
Electro elastic actuator; Piezoactuator; Structural-parametric model; Parametric structural schematic diagram; Transfer function.
Abstract
The generalized parametric structural schematic diagram, the generalized matrix equation for the electro elastic actuator for the nanotechnology and the biotechnology are obtained. The deformations of the electro elastic actuator are described by the matrix equation. The structural-parametric model and the parametric structural schematic diagram of the electro elastic actuator or the piezoactuator are determined in contrast the electrical equivalent circuit types Cady or Mason for the calculation of the piezoelectric transmitter and receiver, the vibration piezomotor with the mechanical parameters in form the velocity and the pressure. The parametric structural schematic diagram of electro elastic actuator is obtained with the mechanical parameters the displacement and the force. The transfer functions of the electro elastic actuator are determined. The method of mathematical physics is used.
Introduction
The electro elastic actuator for the nanotechnology and the biotechnology is used in the scanning tunneling microscopes, the scanning force microscopes, the atomic force microscopes[1-19].
The nano - and micromanipulators with the electro elastic actuators are part of the equipment of the precision engineering, the adaptive optics and the medical surgical manipulators. The piezoactuators are used in the medical technology for the accurate instrument delivery, in the laser equipment for the controlling radiation power and the beam divergence in the optical beam scanning systems[1-8,14].
The piezoactuators are used for the nanodisplacement in the spectrometers, the tunnel microscopes, the interferometers, where the high positioning accuracy and the parallelism of the elements displacement are required simultaneously with the small ranges of the displacements.
As the result of the joint solution of the wave equation of the electro elastic actuator with the Laplace transform, the equation of the electro elasticity and the boundary conditions on the two loaded working surfaces of the electro elastic actuator, we obtain the corresponding structural - parametric model and the parametric structural schematic diagram of the electro elastic actuator
The parametric structural sсhematic diagram of the electro elastic actuator on the piezoelectric, piezomagnetic, electrostriction effects, for example, the piezoactuator is determined in contrast electrical equivalent circuit types Cady or Mason for the calculation of the piezotransmitter and piezoreceiver, the vibration piezomotor with the mechanical parameters in form the velocity and the pressure[1-8]. The parametric structural schematic diagram of the actuator is obtained with the mechanical parameters the displacement and the force.
The method of mathematical physics is applied for the solution of the wave equation of the electro elastic actuator for the nanotechnology and biotechnology with using the Laplace transform for the construction the parametric structural schematic diagram of electro elastic actuator.
The parametric structural schematic diagram and the matrix transfer functions of the electro elastic actuator for the nanotechnology and biotechnology are obtained from the structural - parametric model of the electro elastic actuator with the mechanical parameters the displacement and the force. The parametric structural schematic diagrams of the voltage - controlled or current - controlled piezoactuator are determined from the generalized structural-parametric model of the electro elastic actuator.
Parametric structural schematic diagram
For the determination of the structural-parametric model and the parametric structural schematic diagram of the electroelastic actuator let us consider the generalized equation of the electroelasticity[8,11,18] in the form
(1)
where si = ∂ξ(x,t)/∂x is the relative displacement along axis i of the cross section of the piezoactuator or the piezoplate, Ψm = {Em, Dm is the control parameter E for the voltage control, D for the current control along axis m, Tj is the mechanical stress along axis j, dmi is the coefficient of electro elasticity, for example, the piezomodule, is the elastic compliance for the control parameter Ψ = const, the indexes i, j = 1, 2, … , 6; m = 1, 2, 3.
The main size is determined us the working length for the electro elastic actuator or the piezoactuator in form the thickness, the height and the width for the longitudinal, transverse and shift piezo effect.
For the construction the parametric structural schematic diagram of electro elastic actuator in nanotechnology is used the wave equation[8,11,18] for the wave propagation in a long line with damping but without distortions.
With using Laplace transform is obtained the linear ordinary second-order differential equation with the parameter p. correspondingly the original problem for the partial differential equation of hyperbolic type using the Laplace transform is reduced to the simpler problem[8,11,12] for the linear ordinary differential equation
(2)
With its solution
(3)
where Ξ(x,p) is the Laplace transform of the displacement of section of the actuator, g = p/cψ + a is the propagation coefficient, cψ is the sound speed for the control parameter Y=const, a is the damping coefficient, C and B are constants.
The generalized structural-parametric model and the generalized parametric structural schematic diagram of the electro elastic actuator the nanotechnology and the biotechnology on Figure 1 are determined, using equation of the electro elasticity (1) and the linear ordinary differential equation (2), the boundary conditions on loaded faces and the strains along the axes, in the following form
(4)
Where
vmi is the coefficient of the electroelasticity, for example, dmi is the piezomodule for the voltage-controlled piezoactuator, gmi is the piezomodule for the current-controlled piezoactuator, S0 is the cross section area and M1, M2 are the displaced mass on the faces of the electroelastic actuator, Ξ1(p) ,Ξ2(p) and F1(p), F2(p) are the Laplace transform of the displacements and the forces on the faces of the electroelastic actuator, Ψm is the control parameter of the electroelastic actuator.
Figure 1: Generalized parametric structural schematic diagram of electro elastic actuator in nanotechnology.
The matrix state equations[2,11,14] for the piezoelectric effect have the form
(D) = (d)(T) + (εT)(E) (5)
(S) = (sE) (T) +(d)t (E) (6)
where the first equation describes the direct piezoeffect, the second equation presents the inverse piezoeffect, (D) is the column - matrix of the electric induction along the coordinate axes, (S) is the column-matrix of the relative deformations, (T) is the column - matrix of the mechanical stresses, (E) is the column - matrix of the electric field strength along the coordinate axes, (d)t is the transposed matrix of the piezoelectric modules, (sE) is the elastic compliance matrix, (εT) is the matrix of dielectric constants.
The deformation of the piezoactuator corresponds to its stressed state. If the mechanical stress T are created in the piezoactuator, the deformations S are formed in the piezoactuator[8,11].
There are the six stress components T1, T2 , T3, T4, T5, T6. The components T1 - T3 are defined to extension - compression stresses, the components T4 - T6 are related to shear stresses.
Let us consider the transverse piezoelectric effect in the piezoactuator. The equation of the inverse transverse piezoeffect[8,11] in the piezoactuator can be written in the following form
S1 = d31E3(t) + T1(x,t) (7)
where where S1 = ∂ξ(x,t) / ∂x is the relative displacement of the cross section of the piezoactuator along axis 1, d31 is the piezoelectric module for the transverse piezoeffect, is the elastic compliance for E = const along axis 1, T1 is the stress along axis 1.
The solution of the linear ordinary second-order differential equation with the parameter p (2) can be written as (3) and subject to the conditions
Ξ (0,p) = Ξ1(p) For x = 0, (8)
Ξ (h,p) = Ξ2(p) For x = h,
Therefore the constants C and B for the solution we obtain in the following form
(9)
Then, the solution of the linear ordinary second-order differential equation (2) in form (3) can be written as
(10)
The equations of forces acting on the faces of the piezoactuator has the form
T1(0,p) S1 = F1(p) + M1p2 Ξ1(p) For x = 0 (11)
T1(h,p) S0 = -F2(p) + M2p2 Ξ2(p) For x = h
where and are determined from the equation of the inverse transverse piezoeffect. Therefore we obtain the system of the equations for the mechanical stresses at the faces of the actuator for the transverse piezoeffect in the form
(12)
The set of equations (12) for mechanical stresses in piezoactuator yields the following set of equations describing the structural parametric model and parametric structural schematic diagram of the voltage-controlled piezoactuator for the transverse piezoelectric effect on Figure 2
(13)
Where , l = h.
Figure 2: Parametric structural schematic diagram of voltage - controlled piezoactuator for transverse piezoelectric effect.
The parametric structural schematic diagrams of the voltage - controlled or current-controlled piezoactuator for the transverse, longitudinal, shift piezoelectric effects are determined from the generalized structural-parametric model of the electro elastic actuator.
Transfer functions
From generalized structural-parametric model of the electro elastic actuator, taking into account the generalized equation of the electro elasticity, wave equation and the equation of the forces on its faces, we obtain the transfer functions of the electro elastic actuator. Correspondingly the Laplace transforms of displacements for two faces of the actuator are dependent from the Laplace transforms of the general parameter of control and forces on two faces
Ξ1(p) = W11(p)Ψm (p) + W12(p)F1(p) + W13(p)F2(p) (14)
Ξ2(p) = W21(p)Ψm (p) + W22(p)F1(p) + W23(p)F2(p)
Matrix equation of the Laplace transforms of the displacements with the matrix transfer functions of the electro elastic actuator is obtained[8, 14, 18] in the form
(15)
Let us consider the displacements the faces of the voltage-controlled the piezo actuator for the transverse piezoeffect Ψm = E3 with the output parameter displacement. The transfer functions of the voltage-controlled the piezoactuator for the transverse piezoeffect can be written in the form
The static displacement of the faces the electro elastic actuator ξ1(∞) and ξ2(∞) can be written in the form
Where m is the mass actuator, M1, M2 are the load masses.
Let us consider example at m << M1 and m << M2 for the voltage-controlled the piezoactuator from PZT under the longitudinal piezoeffect d33 = 4.10-10 m/V, U = 150 V, M1 = 1 kg and M2 = 4 kg we obtain the static displacements of the faces of the piezo actuator ξ1(∞) = 48 nm, ξ2(∞) = 12 nm, ξ1(∞) + ξ2(∞) = 60 nm.
The static displacements of the faces for the voltage-controlled the piezoactuator for the transverse piezoeffect are obtained from (15) at m << M1 and m << M2 in the form
For the voltage-controlled the piezoactuator from PZT under the transverse piezoeffect at m << M1 and m << M2, d31 = 2.10-10 m/V, h/d = 20, U = 100 V, M1 = 2 kg and M2 = 8 kg the static displacements of the faces the piezoactuator are determined ξ1(∞) = 320 nm, ξ2(∞) = 80 nm, ξ1(∞) + ξ2(∞) = 400 nm.
The transfer function of the voltage - controlled transverse piezoactuator is obtained from (15) for elastic-inertial load at M1 → ∞, m << M2 and the approximation the hyperbolic cotangent by two terms of the power series in the form
(21)
Where the Laplace is transform of the voltage, Tt is the time constant and ξt is the damping coefficient of the piezoactuator. Therefore the expression for the transient response of the voltage-controlled transverse piezoactuator is determined in the following form
(22)
Where ξm is the steady-state value of displacement for the voltage-controlled piezoactuator, Um is the amplitude of the voltage in the steady-state. For M1 → ∞, m << M2· Um = 50 V, d31 = 2·10-10 m/V, h/d = 20, M2 = 4 kg, C11E = 2.4 * 107N/m, Ce = 0.1 * 107H / m we obtain values the steady-state value of displacement and the time constant of the actuator ξm = 192 nm, Tt = 0.4·10-3 c.
The matrix transfer functions of the actuator are determined for control systems with the electro elastic actuator for the nanotechnology and the biotechnology.
In this work the generalized parametric structural schematic diagram and generalized structural - parametric model of the electro elastic actuator are obtained. From generalized structural - parametric model of the electro elastic actuator after algebraic transformations the transfer functions of the electro elastic actuator are determined. The parametric structural schematic diagrams, the structural-parametric models of the piezoactuator for the transverse, longitudinal, shift piezoelectric effects are determined from the generalized structural-parametric model of the electro elastic actuator for the nanotechnology and the biotechnology.
Conclusion
For the nanotechnology and the biotechnology the generalized parametric structural schematic diagram and the generalized structural - parametric model of the electro elastic actuator are constructed with the mechanical parameters the displacement and the force.
The parametric structural schematic diagrams of the piezoactuator for the transverse, longitudinal, shift piezoelectric effects are determined.
The matrix transfer functions of the electro elastic actuator are determined in the control systems for the nanotechnology and the biotechnology.
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