Theoretical Electrical Engineering and Electrophysics
UDC 621.3.013
V.S. Grinchenko, K.V. Chunikhin, N.V. Grinchenko
10.20998/2074-272X.2016.2.03
LOW-FREQUENCY MAGNETIC FIELD SHIELDING BY A CIRCULAR PASSIVE LOOP AND CLOSED SHELLS
Purpose. To analyze the shielding factors for a circular passive loop and conductive closed shells placed in a homogeneous low-frequency magnetic field. Methodology. We have obtained simplified expressions for the shielding factors for a circular passive loop and a thin spherical shell. In addition, we have developed the numerical model of a thin cubical shell in a magnetic field, which allows exploring its shielding characteristics. Results. We have obtained dependences of the shielding factors for passive loops and shells on the frequency of the external field. Analytically determined frequency of the external magnetic field, below which field shielding of a passive loop is expedient to use, above which it is advisable to use a shielding shell. References 10, figures 4. Key words: shielding factor, magnetic field, circular passive loop, thin shell.
Проведен сравнительный анализ эффективности экранирования однородного низкочастотного магнитного поля электропроводящим кольцом и замкнутыми оболочками. Получены упрощенные выражения для эффективности экранирования магнитного поля электропроводящим кольцом и тонкостенной сферической оболочкой. Разработана численная модель тонкостенной кубической оболочки в магнитном поле, позволяющая исследовать её экранирующие характеристики. Приведены зависимости эффективности экранирования кольцом и замкнутыми оболочками от частоты внешнего поля. Аналитически определена частота внешнего магнитного поля, ниже которой для экранирования поля целесообразно использовать электропроводящее кольцо, выше которой целесообразно использовать замкнутую оболочку. Библ. 10, рис. 4.
Ключевые слова: эффективность экранирования, магнитное поле, электропроводящее кольцо, тонкостенная оболочка.
Introduction. Negative effect of the magnetic field (MF), in particular the low-frequency magnetic field, on the human health [1] as well as limitations on levels of MF in which the stable operation of modern equipment is guaranteed [2] require reducing values of magnetic flux density to accepted ones.
Let's consider a problem of the homogeneous low-frequency MF mitigation in a local domain. Shielding systems are divided into passive and active by the way of power supply. In some works [3, 4] there is proposed to use systems of active shielding for the MF mitigation in the local domain. However, in this work the consideration will be limited by passive electromagnetic shielding. To reduce the external MF in the local domain the electromagnetic shields are manufactured as thin closed shells and usually they have shape of a box or a cylinder with equipment located inside them [5-9]. In [9] there was proposed to use a circular passive loop for the low-frequency MF shielding. In [10] an expression for the shielding factor was written more exactly, and radius of the domain within the circular passive loop in which it is recommended to place equipment was determined.
The goal of this work is to compare shielding properties of the circular passive loop (see Fig. 1,a) and thin closed shells (see Fig. 1,b,c) at various frequencies of the external MF as well as to determine a criterion of utilization of one or another shielding element.
\Bo
z
/ /
\Bo
b
Fig. 1
At the analysis shells of cubic and spherical shapes are considered. A shielding shell has the spherical shape
seldom but frequently closed shields of various shape can be approximately substituted by a spherical shield of the equivalent volume in such a way that three coordinate dimensions of the substituted shield approach to the diameter of spherical one [5].
The MF shielding by a circular passive loop. Shielding factor SF is the ratio of the RMS value of the external magnetic flux density to the RMS value of the magnetic flux density at the utilization of the shield. Let's assume that a circular passive loop of the radius r with a round cross-section of the radius r2 is placed in the homogeneous low-frequency MF (see Fig. 1,a). The loop's plane is oriented perpendicular to the external MF, and the magnetic flux density complex amplitude is
B0 = ez ■ B0, where B0 is the external MF amplitude, ez is the ort. The frequency of the external MF is f Hz. Then, the shielding factor for the circular passive loop [10] in the sighting point (r, z) equals to
SF _
Bo
(1)
Bo + Bfa
n coil Br
where
Bcoil _
Ho1
V(l + r )2
2к
2 2 2 Г1 - r - z
(r1- r f
+z
■ E (k ) + K (k )
n coil Br _-
Ho1 z
2кг
+ z
2
2,2.2 Г1 + r + z
(r1- r f
+z
■E (k )- K (k )
are components of MF created by the inducted in the passive loop current; the complex amplitude of the current is
n__r1 B0 .
M0 " ° "
I _-
1
7 8r1 .
--ln—1 + j---
4 r2 Ho к/СТГ2
© V.S. Grinchenko, K.V. Chunikhin, N.V. Grinchenko
2
2
+
2
z
a
c
ni 2
K (k ) = J
dç
V2 2 1 - k sin ç
ni 2 _
)= J - k2 sin2 ç dç
are complete elliptic integrals of the 1st and the 2nd kind,
J 4 n r
--1-- is the numerical coeffi-
(r1 + r )2 + z 2
cient; a is the loop's conductivity, Sim; fi0 = 4^T0-7 Him is the magnetic constant; j is the imaginary unit.
As it was shown in [10], if r1 is the passive loop radius then it is useful to limit the shielding domain located in its central part by a sphere of radius r1i2. The shielding factor SF is a function of the sighting point coordinates. Minimal SF takes places on the shielding domain's bound
on the circular loop's axis: SFcoii = SF I r = 0, z =
SFcoil =
16n2
8n
1+-
125 5>/5 I 4
7 - ln8rn
7
8r,
\2 (
--ln^1 4 r2
1
(2)
SF (Kaden) = sphere ~
ch kds +
K +-
• sh kds
(3)
2
SFs
sphere
1
1 +
U0 2nf cRds
3
(4)
The MF shielding by a conductive cubic shell.
Analytical calculation of the MF within a conductive cubic shell placed in the external MF (see Fig. 1,c) is very difficult. Therefore, it is useful to use the numerical modeling. Because of the exciting field is low-frequency, the MF is described by the equation obtained from the Am-
pere's circuital law in quasi-static approach:
i K ) = -Â (e) = 0,
A (i ) = - j u02nf c (i),
2
Using (1) we obtain the final expression for the circular passive loop's shielding factor:
where A', Ae are complex amplitudes of the vector
potential of the electromagnetic field inside and outside the cubic shell's walls, respectively; a is its conductivity, S/m. In (5) the cubic shell relative permeability is assumed to be equal 1.
To «link» solutions of the system (5) it is necessary to set conditions on the interface of the air region and conductive shell's walls:
Ui' ) = Aie), ^ 4AM), (6)
where the index t indicates that tangential for the interface vectors components are taken.
On the calculation region's bound the MF is supposed to be undisturbed, and the magnetic potential is set to equal to
rotl
Ji^nf ar2
The MF shielding by a conductive spherical shell.
A problem of the MF determination within a thin conductive spherical shell placed in the homogeneous low-frequency MF (see Fig. 1,b) is considered in [5]. In this work the calculation of the shielded MF is carried out at the following assumptions. Firstly, the shell thickness ds is supposed to be much less than the MF penetration depth to the conductor 8. Secondly, the thickness ds is supposed to be much less than the shell radius R. At these assumptions the MF within the shell is homogeneous, and the shielding factor equals to
Âx = -y • 30/2,
Ây = x • B0/2,
(7)
Âz = 0,
where K = kR and k = j ¡M2nf a H—- are the nondi-
R2
mensional coefficient and the coefficient with dimensionality m-1, respectively; a is the spherical shell conductivity, S/m. In (3) the spherical shell relative permeability is assumed to be equal 1.
For the considered in the present work dimensions and frequencies the following relation takes place: 8<<R. Considering the expansion of the second member of (3) by the small parameter 8/R, we obtain the expression for the shielding factor for the conductive spherical shell placed in the homogeneous low-frequency MF:
where x, y are coordinates of the point on the calculation region's bound. For the correct utilization of (7), the calculation region's dimension is selected much more that the cubic shell edge.
The described problem is solved by the Finite Element Method using the software package COMSOL Mul-t'phys'cs. To solve the problem, the interface «Magnetic Fields» which is a part of the «AC/DC Module» was used. This interface permits to model processes described by the equations (5). Building the 3D model for the option «Space Dimension», the variant «3D» was set. In all domains the mesh «Free Tetrahedral» was used, and within the cubic shell walls the mesh was finest.
Input parameters of the model are the amplitude B0 and the frequency f of the external MF, the conductivity a, the edge length a, and the walls thickness dc of the cubic shell. The calculation result is the distribution of the RMS value of the magnetic flux density Brms(x,y,z).
The cubic shell placed in the homogeneous MF
B0 = ez • B0 is shown in Fig. 2. The MF frequency is equal to 150 Hz. The borders of the cubic shell are shown by a dashed line. The shell is made of copper, the edge length is equal to 0.3 m, and the wall thickness is equal to 0.27 mm. The isolines in the Fig. 2 correspond to values
of SF-1(x, y, z ) =
Brms ^ z)
B0/V2
from 0.8 to 1.05. The dis-
tribution is built in the plane y = 0. In the center of the shell under consideration SF-1 = 0.81. Hence, the variation of SF-1 within the shell is less than 1 %. Therefore, the shielding factor for the cubic shell is determined as
Bp A/2"
SFcube = min <
Brms ^ У, z )
i
x2 + y2 + z2
a I < ? !
r
2
2
+
2
0.30
0.20
0,10
0,00
-0.10
-0,20
-0.30
-0.30 -0.20 -0.10
0.00 x, m
0.10
0.20
0.30
passive loop
sphere shell cubic shell
Fig. 2
The comparison of shielding factors for a passive loop and shells. Let's determine the dependence of the shielding factors on the external field frequency for a circular passive loop and conductive shells (spherical and cubic) placed in the homogeneous low-frequency MF. We assume that a passive loop and shells are made from copper with conductivity a = 5.41107 S/m. The passive loop radius is assumed to be r1=0.3 m. We consider two cases when the loop's cross-section radius r2 equals to 2.5 mm and 5 mm. Because of the domain of the shielding by the circular passive loop is a sphere of the radius of r1/2 [10], for the comparison of the passive loop's and shells' shielding characteristics let's assume the spherical shell radius R = r1/2 and the cube edge length a = r1. Besides, for the correctness of the shielding characteristics comparison, the passive loop's and shells' metal intensities should be the same. Therefore, the spherical shell thickness ds and cubic shell one dc are determined as follows:
ds = 2^r22/rU dc = ("r2 f/(3rl).
In Fig. 3 the shielding factor dependence on the external MF frequency in the case r2 = 2.5 mm is represented. The full line corresponds to SFcoih the dashed line corresponds to SFsphere, and dots correspond to SFcube. The dependences SFcoi(f) and SFsphere(f) are obtained by using analytical expressions (2) and (4), respectively. The dependence SFcube(f) is obtained by interpolation of numerical modeling results depicted by dots in Fig. 3.
From the presented dependences it can be seen that at frequencies less than f0 = 217 Hz the effectiveness of the shielding by the circular passive loop is higher that the effectiveness of the shielding by the spherical shell. From physical point of view, it can be explained by the change of the mechanism of the MF mitigation in the shielded domain. At f < f0 the MF mitigation is determined by the inducted conduction current only, but at f > f0 it is necessary to take into account the contribution of the MF attenuation in the shell's walls. As it is shown from Fig. 3 at frequencies 200-250 Hz the shielding factor equals to 1.15-1.20.
Fig. 3
As it was supposed the cubic shell's shielding characteristics are lower in the comparison with spherical one's at all frequency spectrum. In its turn, the cubic shell's shielding characteristics are lower than passive loop's ones at frequencies less than 454 Hz that is two times greater than f0 (see Fig. 3).
In Fig. 4 the shielding factor dependence on the external MF frequency in the case r2 = 5 mm is represented. In this case, f0 equals to 56 Hz.
The shielding factor is higher than in the previous case that is explained by the metal intensity increase in four times. However, the curves' character is the same. As it can be seen from Fig. 4 the shielding factor of 1.15-1.20 is reached at frequencies 50-60 Hz.
— passive loop
- - - sphere shell ■ cubic shell
Fig. 4
As the shells' metal intensity increases, their walls' thickness increases too. As a result, the penetration depth 8 at which the absorption mechanism becomes prevailing in the MF shielding increases, too. Therefore, as the metal intensity increases the value of the frequency f0 decreases. The value of the frequency f0 can be obtained analytically from the equation
SFc
? = SF
coil\f_fo oi spheref _
fo
fo _
Using (2) and (4) we obtain:
6 R
Mo& V
-—+ ln(32^)+ — ln— 4 v ' 2 V
4n 7
5V5 4
7 1 R
-- + ln(32tf) + - ln—
x
x
where V = 2nrynr2 = 4nR -ds is the metal intensity of the circular passive loop and shell; R is the radius of the shielded domain.
Calculating the numerical coefficients with precision till three significant digits, we obtain the final expression for f:
12,7
R
V
f0 -—~'77'
i
R3
0,694 + ln—
V
R3
3,47 + ln—
V
So, in the region f >f in order to mitigate the MF in the region of the radius R at given metal intensity V it is useful to use the closed conductive shell. If the external MF frequency f < f0, it is useful to use the circular passive loop with radius 2R.
Conclusions.
1. Analytical expressions for shielding factors for the circular passive loop and conductive spherical shell are obtained which together with developed numerical model of the cubic shell permit to compare their effectiveness of the external MF shielding at various frequencies.
2. The external MF frequency f0 is determined which can serve as a criterion of the expediency of the circular passive loop utilization. At the MF frequency less than f0, the passive loop shielding factor is higher than the shielding factor for the equivalent volume spherical shell. At the MF frequency less than 2f0, passive loop shielding factor is higher than the shielding factor for the equivalent volume cubic shell.
3. Rozov V.Yu. Assuirov D.A. Method of the active shielding of technical objects external magnetic field. Tekhnichna elektrodynamika - Technical electrodynamics, 2006, no.3, pp. 13-16. (Rus).
4. Kuznetsov B.I., Nikitina T.B., Bovdui I.V., Voloshko A.V., Vinichenko E.V., Kotliarov D.A. Active screening of magnetic field near power station generator buses. Elektrotekhnika i elektromekhanika - Electrical engineering & electromechanics, 2013, no.6, pp. 66-71. (Rus).
5. Kaden H. Wirbelstrome und Schirmung in der Nachrichtentechnik. - Springer Berlin Heidelberg, 1959. doi: 10.1007/978-3-540-32570-3.
6. Buccella C., Feliziani M., Maradei F., Manzi G. Magnetic field computation in a physically large domain with thin metallic shields. IEEE Transactions on Magnetics, 2005, vol.41, no.5, pp. 1708-1711. doi: 10.1109/TMAG.2005.846059. ZKistenmacher P., Schwab A. Low-frequency shielding effectiveness of inhomogeneous enclosures. Proceedings of IEEE International Symposium on Electromagnetic Compatibility, 1996, pp. 347-352. doi: 10.1109/ISEMC.1996.561256.
8. Clairmont B.A., Lordan R.J. 3-D modeling of thin conductive sheets for magnetic field shielding: calculations and measurements. IEEE Transactions on Power Delivery, 1999, vol.14, no.4, pp. 1382-1393. doi: 10.1109/PESW.1999.747382.
9. Roginskiy V.Yu. Ekranirovanie v radioustroystvah [Shielding in radio devices]. Leningrad, Energiya Publ., 1969. 112 p. (Rus).
10. Grinchenko V.S., Chunikhin K.V. Shielding of a uniform alternating magnetic field using a circular passive loop. Elektrotekhnika i elektromekhanika - Electrical engineering & electromechanics, 2015, no.2, pp. 31-34. (Rus).
Received 11.01.2016
REFERENCES
1. International Commission on Non-Ionizing Radiation Protection. ICNIRP Guidelines for limiting exposure to time-varying electric and magnetic fields (1 Hz-100 kHz). Health Physics, 2010, vol.99, no.6, pp. 818-836. doi: 10.1097/HP.0b013e3181f06c86.
2. Korol' E.G., Pantelyat M.G. EMC requirements of technical devices at electric power facilities and industrial. Visnyk NTU «KhPI» - Bulletin of NTU «KhPI», 2013, no.15, pp. 35-60. (Rus).
V.S. Grinchenko1, Candidate of Technical Science, K.V. Chunikhin1,
N.V. Grinchenko2, Candidate of Technical Science,
1 State Institution «Institute of Technical Problems of Magnetism of the NAS of Ukraine»,
19, Industrialna Str., Kharkiv, 61106, Ukraine,
e-mail: [email protected], [email protected]
2 Ukrainian State University of Railway Transport, 7, Feuerbach Sq., Kharkiv, 61050, Ukraine.
How to cite this article:
Grinchenko V.S., Chunikhin K.V., Grinchenko N.V. Low-frequency magnetic field shielding by a circular passive loop and closed shells. Electrical engineering & electromechanics, 2016, no.2, pp. 20-23. doi: 10.20998/2074-272X.2016.2.03.