Voltage Generation by Rotating an Arbitrary-Shaped Metal Loop around Arbitrary Axis in the Presence of an Axial Current Distribution

A thin metallic wire loop of arbitrary curvature is rotated with respect to an arbitrary axis of its plane. The device is excited by an electric dipole of infinite length and constant current. The resistance of the loop is computed rigorously as function of the position of the source. In this way, the induced voltage along the wire, under any kind of axial excitation, is given in the form of a superposition integral. The measured response is represented for various shapes of the coil, with respect to the time, the rotation angle and the position of the source. These diagrams lead to several technically applicable conclusions which are presented, discussed and justified.


Introduction
Electromagnetic (EM) induction is the production of voltage across a conductor situated in a changing magnetic field or a conductor moving through a stationary magnetic field.The physics that govern the inductive experiments have been mathematically examined in a number of old and elementary studies.The relationship between the various induction laws is summarized in [1] where Cohn advocates that the combined use of both motional and transformer induction assures the validity of the produced results.The Faraday's disk, the typical DC generator, a cumulative magnet and other inductive structures are thoroughly investigated.Hvozdara also has contributed significantly in analyzing and solving rigorously some basic configurations where the EM induction phenomenon appears.For example in [2], the magnetotelluric field for a cylindrical inhomogeneity in a half space with anisotropic surface is evaluated, while in [3] is shown theoretically what effects are generated if one considers the rotation of a spherical Earth in an external inhomogeneous time-variable magnetic field.Moreover, a rudimentary study of induction in a rotating conductor surrounded by a rigid conductor of finite or infinite ex-tent has been provided in [4].The analysis is based on integral solutions of the field equations and leads to the conclusion that the induced magnetic fields depend on the relative symmetry of the rotator.
Many solving techniques have been utilized to convert the aforementioned theoretical analyses into practical applications in real-world configurations.For example in [5], a 3-D finite-element general method is presented to treat controlled-source induction problems in heterogeneous media.It can be used efficiently for EM modeling in mining, groundwater, and environmental geophysics in addition to fundamental studies of EM induction within a heterogeneous environment.Furthermore, many patents and inventions such as [6], exploit inductive phenomena to generate high-voltage power.In particular, the power capability of core-type transformers is increased by creating additional magnetomotive force in certain secondary coils without any subsequent power loss.Also in [7], a highly applicable technique is presented which describes finite-difference approximations to the equations of 2-D EM induction that permits discrete boundaries to have arbitrary geometrical relationships to the nodes.
Apart from the old standard textbooks and the newer technical reports, there are numerous recent, state-ofthe-art references examining devices and presenting techniques which exploit electromagnetic induction.In [8], a new electromagnetic induction detection mode for Capillary Electrophoresis (CE) and microfluidic chip CE has been presented.Its own optimal operating conditions are determined, and its application in CE and microfluidic chip CE of inorganic ions is described.A study [9] tests the validity of using electromagnetic induction (EMI) survey data, a new prediction-based sampling strategy and ordinary linear regression modeling to predict spatially variable feedlot surface manure accumulation.In addition, a flow injection system incorporating electromagnetic induction heating oxidation for on-line determination of chemical oxygen demand has been proposed [10].The procedure utilizes induction heating instead of conventional reflux heating, with acidic potassium dichromate acting both as an oxidant and as a spectrometric reagent.Finally, a general-purpose analysis is contained in [11], where the law of induced electromotive force is applied to three significant cases: moving bar, Faraday's and Corbino's disc.
In this work, we assume a closed metallic wire of arbitrary shape which is mechanically rotated with respect to an arbitrary axis of its plane, in the presence of an elemental source of infinite length and constant current.The parametric equation of the wire curve is extracted through coordinate transformations and the magnetic flux through the loop is evaluated straightforwardly.To this end, we apply the Faraday's law and an expression for the coil's resistance is derived.This study examines the voltage induction to the most general case of a single wire loop (shape and rotation axis can be altered at will) which has not been treated rigorously yet.However, the basic novelty of the present analysis is that, due to the linearity of the participating operators, the calculus can be generalized to cover any case of axial excitation.We compute a kind of "Green's function" ([12]) for the loop impedance, corresponding to a point source excitation.Therefore, the solution for more complex axial currents utilized in industry and technology is given through an integral of that resistance function multiplied by the current distribution of the source.A set of computer programs has been developed to evaluate the formulas, the induced voltage is represented as function of the time, the rotation angle and the position of the source for various loop shapes, while the produced graphs are presented and discussed.

Problem Statement
The Cartesian coordinate system ( , , ) x y z defined in Figure 1(a) will be used throughout the analysis.We suppose an infinite axial dipole into vacuum, parallel to axis, at the position y Amperes).A wire loop is located around the origin on the ( , ) x y plane, and its shape is determined by the radial distance ( ) respect to the aforementioned axis.Initially ( 0) t  , the curve lies entirely on the ( , ) x y plane.The purpose of this work is to obtain an expression for the electromotive force induced at the coil, being dependent on the time t , the rotation axis  and the shape of the loop ( ) P  .The generated voltage should certainly vary with the position of the primary source ( , ) X Z , and thus the derived formula could be used in studying structures with more complicatedly distributed excitation current.

Mathematical Formulation
Firstly, we should extract the parametric equation set of the rotated loop when 0   as appeared in Figure 1.
The equations will be denoted by { ( ), ( ),  , upon the axes x and Z .Accordingly, one obtains the fol- lowing expressions: In order to find the parametric equation of the curve when 0 , we use the primed coordinate system ( , x y z   which is received through rotation of the unprimed one by angle  with respect to axis Z (defined in Figure 1(b)).The polar equation of the loop is now given by ( ) , while the two azimuthal angles are connected obviously via the relation . Therefore, we take the Formulas (1)-( 3) replacing by and the unprimed variables  x y z  by the primed ones { , , , } x y z      .In this sense, the parametric set of the primed coordinates with respect to unprimed azimuthal angle  (after trivial algebraic manipulations), is written as follows: The parametric equations of the arbi loop expressed in the unprimed coor , An extra time argument has been added to the depe pr quantities related to the induced volt-ndencies of the parametric equations for better comehension.
Once the boundary of the rotating wire is rigorously specified, the field age can be computed.The magnetic vector potential of a y -polarized infinite dipole into vacuum at distance D from its axis is given by [14]: where is the reference distance, 0 D 0  is the vacuum magnet ermeability and y is the itary vector of the y axis.The transverse distance of the representative loop point with azimuthal angle ic p un  , at an arbitrary time t , from the axis ( , ) , is found apparently equal to: also shown in Figure 2. It is well-known [15] that the magnetic flux through a closed loop ( ) W is defined from the line integral of the magnetic potential on the curve, that is  A W .In our case, this formula is particularized [16] to give: where the subscript notation is used for the partial derivative of a function.It should be noted that the magnetic flux is independent from the reference distance 0 D .According to Faraday's law, the induced electromotive force is given by the time derivative of magnetic f / U dΨ dt lux   ; therefore, it is sensible to define the following auxiliary resistance function by excluding ( , ) I X Z from (10): (,, , ) 0 ( , , ) Z ( , , , ) ln ( , ) In this way, the generated voltage on the coil due t o the self-rotation, in the presence of a dipole posed along the axis ( , ) x X z Z   , is given by: In case the structure is excited by an axial surface current distributed according to the law ( , ) K X Z (measured in / A M ), along the line d electromotive force on the wire loop, is th ( ) L , the induce expressed in terms of e following line integral: Such an expansion is permissible because the operator )dL ( )

Indicative Results
In this se the voltage is obtaine low: ction, we examine the produced voltage by rotating loops of variable shape and the ef metrical parameters on it.The described method is apwire boundaries possessns: fect of their geoplied to two families (A, B) of ing the following polar equatio ( , , , ) cos sin A single wire loop is not practically used for voltage generation as clusters of coils are utilized instead.We are more concerned for the qualitative description of the output quantity than measuring t Volts) of the produced voltage which is extremely small.A In F he exact magnitude (in ccordingly, the so-called "normalized voltage" is represented alternatively which is evaluated by replacing the magnetic permeability of the vacuum .The observation duration is a single period as from that cal sym point on the procedure and the results are repeated unchanged.Even though the shape of the wire is arbitrary, the waveforms exhibit typical sinus idal behavior, a fact that can be attributed to the hori d verti metry of the metallic loop boundary.Also, the amplitude of the oscillation gets greater, as the area of the closed wire increases.This is a natural conclusion because by keeping fixed the rotation frequency and the axis parallel to the dipole, larger loops lead to more significant magnetic flux variance and implicitly to more substantial output voltage.Therefore, the oscillation amplitude of the investigated quantity is decaying with increasing n because the occupying area of the loop is greater for   One could point out that the positive effect of the coil's size on the induced measured quantity is greater when the excitation field is stronger (larger differences between the three curves in the vicinity of 0 Z  ).It is al rc so remarkable that the induced voltage is exponentially dependent on the distance between the thin closed wire and the sou e current, which is indicated not only by the decrease for large Z in Figure 6(a) but with the increase for large X in Figure 5(a) as well.

Conclusions
The case of a metallic loop of arbitrary shape rotated with respect to an arbitrary axis in the presence of an infinite dipole is investigated.The induced voltage is evaluated rigorously via transformation relations and the derived formula can be ily generalized to treat any eas kind of axial excitation.The time dependence of the measured voltage is of sinusoidal form only if the shape of the loop combined with the rotation axis is symmetric.Additionally, the intuitive guess that the size of the loop, affects positively the inductive action is verified by the numerical results.The distance between the source and the loop is also found to reduce the measured voltage along the coil.As far as the rotation axis is concerned, the most substantial response has been recorded when it is normal to the axis of the dipole current, a result that can have technical applicability.

Figure 1 (Figure 1 .
Figure 1(b).Consequently, it makes sense just to examine the loop turned by the representative angle t  with

Figure 2 .
Figure 2. The transversal distance between the axis of the dipole and a representative point of the rotated loop projected on x-z plane

2 /
N A in (11), by unity.Each figure below is divided into two subfigures, the first of which is a diagram depicting the variation of the investigated quantities for various shapes of the loop, while the second is a polar plot of the corresponding wire boundaries.igure 3(a), we represent the time dependence of the developed normalized voltage for various shapes of loops corresponding to different n parameters of the curve family A with constant 1

Figure 6 (
a), the variation of the induced voltage is represented as function of the vertical position of the excitation Z (the source is moving normally to the plane of the sheet) for various loops from curve family B corresponding to different lengths b (with fixed 1.In all the three cases the response is maximized for 0 Z  which is a al result because the loop is at the closest distance from the excitation axis.In addition, the curves are symmetrical with respect to 0 Z  , due to t t the loops are symmetric with respect to the rotation axis which is parallel to that of the source ( 0 n r he fact tha atu   ) as shown in Figure 6(b).

Figure 6 .
Figure 6.(a) The RMS voltage as function of the vertica l position of the source for various shapes of the loops.(b) The corresponding polar plots of the bounds.Plot parameters: ξ = 0 o , X = -5 m, ω = 100 π rad/sec, D 0 = 1 m, I = 1 A, a = 1.5 m, n = 1 Voltage Generation by Rotating an Arbitrary-Shaped Metal Loop around Arbitrary Axis in 396 the Presence of an Axial Current Distribution